Methods of inducing an immune response

ABSTRACT

Novel genes designated and set forth in FIG.  2  and their respective encoded proteins, and variants thereof, are described wherein a gene of the invention exhibits tissue specific expression in normal adult tissue, and is aberrantly expressed in the cancers such as those listed in Table I. Consequently, of gene products of a gene of FIG.  2  provide diagnostic, prognostic, prophylactic and/or therapeutic targets for cancer. A gene of FIG.  2  or fragment thereof, its encoded protein, or variants thereof, or a fragment thereof, can be used to elicit a humoral or cellular immune response; antibodies or T cells reactive with a gene product of FIG.  2  can be used in active or passive immunization.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of pending U.S. application Ser. No. 10/121,024, filed Apr. 10, 2002, now pending, which claims the benefit of U.S. Provisional Application Ser. No. 60/283,112, filed Apr. 10, 2001; U.S. Provisional Application Ser. No. 60/282,739, filed Apr. 10, 2001; and U.S. Provisional Application Ser. No. 60/286,630, filed Apr. 25, 2001. The contents of these applications are herein incorporated by reference in their entirety.

SUBMISSION ON COMPACT DISC

The content of the following submission on compact discs is incorporated herein by reference in its entirety: A computer readable form (CRF) of the Sequence Listing on compact disc (file name: 511582004001, date recorded: Nov. 14, 2005, size: 983,040 bytes); a duplicate compact disc copy of the Sequence Listing (COPY 1) (file name: 511582004001, date recorded: Nov. 14, 2005, size: 983,040 bytes); and a duplicate compact disc copy of the Sequence Listing (COPY 2) (file name: 511582004001, date recorded: Nov. 14, 2005, size: 983,040 bytes).

STATEMENT OF RIGHTS TO INVENTIONS MADE UNDER FEDERALLY SPONSORED RESEARCH

Not applicable.

FIELD OF THE INVENTION

The invention described herein relates to a gene and its encoded proteins set forth, e.g., in FIG. 2 expressed in certain cancers, and to diagnostic and therapeutic methods and compositions useful in the management of cancers that express a gene of FIG. 2.

BACKGROUND OF THE INVENTION

Cancer is the second leading cause of human death next to coronary disease. Worldwide, millions of people die from cancer every year. In the United States alone, as reported by the American Cancer Society, cancer causes the death of well over a half-million people annually, with over 1.2 million new cases diagnosed per year. While deaths from heart disease have been declining significantly, those resulting from cancer generally are on the rise. In the early part of the next century, cancer is predicted to become the leading cause of death.

Worldwide, several cancers stand out as the leading killers. In particular, carcinomas of the lung, prostate, breast, colon, pancreas, and ovary represent the primary causes of cancer death. These and virtually all other carcinomas share a common lethal feature. With very few exceptions, metastatic disease from a carcinoma is fatal. Moreover, even for those cancer patients who initially survive their primary cancers, common experience has shown that their lives are dramatically altered. Many cancer patients experience strong anxieties driven by the awareness of the potential for recurrence or treatment failure. Many cancer patients experience physical debilitations following treatment. Furthermore, many cancer patients experience a recurrence.

Worldwide, prostate cancer is the fourth most prevalent cancer in men. In North America and Northern Europe, it is by far the most common cancer in males and is the second leading cause of cancer death in men. In the United States alone, well over 30,000 men die annually of this disease—second only to lung cancer. Despite the magnitude of these figures, there is still no effective treatment for metastatic prostate cancer. Surgical prostatectomy, radiation therapy, hormone ablation therapy, surgical castration and chemotherapy continue to be the main treatment modalities. Unfortunately, these treatments are ineffective for many and are often associated with undesirable consequences.

On the diagnostic front, the lack of a prostate tumor marker that can accurately detect early-stage, localized tumors remains a significant limitation in the diagnosis and management of this disease. Although the serum prostate specific antigen (PSA) assay has been a very useful tool, however its specificity and general utility is widely regarded as lacking in several important respects.

Progress in identifying additional specific markers for prostate cancer has been improved by the generation of prostate cancer xenografts that can recapitulate different stages of the disease in mice. The LAPC (Los Angeles Prostate Cancer) xenografts are prostate cancer xenografts that have survived passage in severe combined immune deficient (SCID) mice and have exhibited the capacity to mimic the transition from androgen dependence to androgen independence (Klein et al., 1997, Nat. Med. 3:402). More recently identified prostate cancer markers include PCTA-1 (Su et al., 1996, Proc. Natl. Acad. Sci. USA 93: 7252), prostate-specific membrane (PSM) antigen (Pinto et al., Clin Cancer Res 1996 Sep. 2 (9): 1445-51), STEAP (Hubert, et al., Proc Natl Acad Sci USA. 1999 Dec. 7; 96(25): 14523-8) and prostate stem cell antigen (PSCA) (Reiter et al., 1998, Proc. Natl. Acad. Sci. USA 95: 1735).

While previously identified markers such as PSA, PSM, PCTA and PSCA have facilitated efforts to diagnose and treat prostate cancer, there is need for the identification of additional markers and therapeutic targets for prostate and related cancers in order to further improve diagnosis and therapy.

Renal cell carcinoma (RCC) accounts for approximately 3 percent of adult malignancies. Once adenomas reach a diameter of 2 to 3 cm, malignant potential exists. In the adult, the two principal malignant renal tumors are renal cell adenocarcinoma and transitional cell carcinoma of the renal pelvis or ureter. The incidence of renal cell adenocarcinoma is estimated at more than 29,000 cases in the United States, and more than 11,600 patients died of this disease in 1998. Transitional cell carcinoma is less frequent, with an incidence of approximately 500 cases per year in the United States.

Surgery has been the primary therapy for renal cell adenocarcinoma for many decades. Until recently, metastatic disease has been refractory to any systemic therapy. With recent developments in systemic therapies, particularly immunotherapies, metastatic renal cell carcinoma may be approached aggressively in appropriate patients with a possibility of durable responses. Nevertheless, there is a remaining need for effective therapies for these patients.

Of all new cases of cancer in the United States, bladder cancer represents approximately 5 percent in men (fifth most common neoplasm) and 3 percent in women (eighth most common neoplasm). The incidence is increasing slowly, concurrent with an increasing older population. In 1998, there was an estimated 54,500 cases, including 39,500 in men and 15,000 in women. The age-adjusted incidence in the United States is 32 per 100,000 for men and 8 per 100,000 in women. The historic male/female ratio of 3:1 may be decreasing related to smoking patterns in women. There were an estimated 11,000 deaths from bladder cancer in 1998 (7,800 in men and 3,900 in women). Bladder cancer incidence and mortality strongly increase with age and will be an increasing problem as the population becomes more elderly.

Most bladder cancers recur in the bladder. Bladder cancer is managed with a combination of transurethral resection of the bladder (TUR) and intravesical chemotherapy or immunotherapy. The multifocal and recurrent nature of bladder cancer points out the limitations of TUR. Most muscle-invasive cancers are not cured by TUR alone. Radical cystectomy and urinary diversion is the most effective means to eliminate the cancer but carry an undeniable impact on urinary and sexual function. There continues to be a significant need for treatment modalities that are beneficial for bladder cancer patients.

An estimated 130,200 cases of colorectal cancer occurred in 2000 in the United States, including 93,800 cases of colon cancer and 36,400 of rectal cancer. Colorectal cancers are the third most common cancers in men and women. Incidence rates declined significantly during 1992-1996 (−2.1% per year). Research suggests that these declines have been due to increased screening and polyp removal, preventing progression of polyps to invasive cancers. There were an estimated 56,300 deaths (47,700 from colon cancer, 8,600 from rectal cancer) in 2000, accounting for about 11% of all U.S. cancer deaths.

At present, surgery is the most common form of therapy for colorectal cancer, and for cancers that have not spread, it is frequently curative. Chemotherapy, or chemotherapy plus radiation, is given before or after surgery to most patients whose cancer has deeply perforated the bowel wall or has spread to the lymph nodes. A permanent colostomy (creation of an abdominal opening for elimination of body wastes) is occasionally needed for colon cancer and is infrequently required for rectal cancer. There continues to be a need for effective diagnostic and treatment modalities for colorectal cancer.

There were an estimated 164,100 new cases of lung and bronchial cancer in 2000, accounting for 14% of all U.S. cancer diagnoses. The incidence rate of lung and bronchial cancer is declining significantly in men, from a high of 86.5 per 100,000 in 1984 to 70.0 in 1996. In the 1990s, the rate of increase among women began to slow. In 1996, the incidence rate in women was 42.3 per 100,000.

Lung and bronchial cancer caused an estimated 156,900 deaths in 2000, accounting for 28% of all cancer deaths. During 1992-1996, mortality from lung cancer declined significantly among men (−1.7% per year) while rates for women were still significantly increasing (0.9% per year). Since 1987, more women have died each year of lung cancer than breast cancer, which, for over 40 years, was the major cause of cancer death in women. Decreasing lung cancer incidence and mortality rates most likely resulted from decreased smoking rates over the previous 30 years; however, decreasing smoking patterns among women lag behind those of men. Of concern, although the declines in adult tobacco use have slowed, tobacco use in youth is increasing again.

Treatment options for lung and bronchial cancer are determined by the type and stage of the cancer and include surgery, radiation therapy, and chemotherapy. For many localized cancers, surgery is usually the treatment of choice. Because the disease has usually spread by the time it is discovered, radiation therapy and chemotherapy are often needed in combination with surgery. Chemotherapy alone or combined with radiation is the treatment of choice for small cell lung cancer; on this regimen, a large percentage of patients experience remission, which in some cases is long lasting. There is however, an ongoing need for effective treatment and diagnostic approaches for lung and bronchial cancers.

An estimated 182,800 new invasive cases of breast cancer were expected to occur among women in the United States during 2000. Additionally, about 1,400 new cases of breast cancer were expected to be diagnosed in men in 2000. After increasing about 4% per year in the 1980s, breast cancer incidence rates in women have leveled off in the 1990s to about 110.6 cases per 100,000.

In the U.S. alone, there were an estimated 41,200 deaths (40,800 women, 400 men) in 2000 due to breast cancer. Breast cancer ranks second among cancer deaths in women. According to the most recent data, mortality rates declined significantly during 1992-1996 with the largest decreases in younger women, both white and black. These decreases were probably the result of earlier detection and improved treatment.

Taking into account the medical circumstances and the patient's preferences, treatment of breast cancer may involve lumpectomy (local removal of the tumor) and removal of the lymph nodes under the arm; mastectomy (surgical removal of the breast) and removal of the lymph nodes under the arm; radiation therapy; chemotherapy; or hormone therapy. Often, two or more methods are used in combination. Numerous studies have shown that, for early stage disease, long-term survival rates after lumpectomy plus radiotherapy are similar to survival rates after modified radical mastectomy. Significant advances in reconstruction techniques provide several options for breast reconstruction after mastectomy. Recently, such reconstruction has been done at the same time as the mastectomy.

Local excision of ductal carcinoma in situ (DCIS) with adequate amounts of surrounding normal breast tissue may prevent the local recurrence of the DCIS. Radiation to the breast and/or tamoxifen may reduce the chance of DCIS occurring in the remaining breast tissue. This is important because DCIS, if left untreated, may develop into invasive breast cancer. Nevertheless, there are serious side effects or sequelae to these treatments. There is, therefore, a need for efficacious breast cancer treatments.

There were an estimated 23,100 new cases of ovarian cancer in the United States in 2000. It accounts for 4% of all cancers among women and ranks second among gynecologic cancers. During 1992-1996, ovarian cancer incidence rates were significantly declining. Consequent to ovarian cancer, there were an estimated 14,000 deaths in 2000. Ovarian cancer causes more deaths than any other cancer of the female reproductive system.

Surgery, radiation therapy, and chemotherapy are treatment options for ovarian cancer. Surgery usually includes the removal of one or both ovaries, the fallopian tubes (salpingo-oophorectomy), and the uterus (hysterectomy). In some very early tumors, only the involved ovary will be removed, especially in young women who wish to have children. In advanced disease, an attempt is made to remove all intra-abdominal disease to enhance the effect of chemotherapy. There continues to be an important need for effective treatment options for ovarian cancer.

There were an estimated 28,300 new cases of pancreatic cancer in the United States in 2000. Over the past 20 years, rates of pancreatic cancer have declined in men. Rates among women have remained approximately constant but may be beginning to decline. Pancreatic cancer caused an estimated 28,200 deaths in 2000 in the United States. Over the past 20 years, there has been a slight but significant decrease in mortality rates among men (about −0.9% per year) while rates have increased slightly among women.

Surgery, radiation therapy, and chemotherapy are treatment options for pancreatic cancer. These treatment options can extend survival and/or relieve symptoms in many patients but are not likely to produce a cure for most. There is a significant need for additional therapeutic and diagnostic options for pancreatic cancer.

SUMMARY OF THE INVENTION

The present invention relates to genes and respective encoded proteins set forth in FIG. 2, that have now been found to be over-expressed in the cancer(s) listed in Table I. Northern blot expression analysis of the genes of FIG. 2 in normal tissues shows a restricted expression pattern in adult tissues. The nucleotide (FIG. 2) and amino acid (FIG. 2, and FIG. 3) sequences of FIG. 2 are provided. The tissue-related expression profile of the genes set forth in FIG. 2 in normal adult tissues, combined with the over-expression observed in the tumors listed in Table I, shows that the genes of FIG. 2 are aberrantly over-expressed in certain cancers, and thus serves as a useful diagnostic, prophylactic, prognostic, and/or therapeutic target for cancers of the tissue(s) such as those listed in Table I.

The invention provides polynucleotides corresponding or complementary to all or part of the genes of FIG. 2, corresponding/related mRNAs, coding and/or complementary sequences, preferably in isolated form, including polynucleotides encoding FIG. 2–related proteins and fragments of 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, or more than 25 contiguous amino acids of a FIG. 2–related protein; at least 30, 35, 40, 45, 50, 55, 60, 65, 70, 80, 85, 90, 95, 100 or more than 100 contiguous amino acids of a FIG. 2–related protein, as well as the peptides/proteins themselves; DNA, RNA, DNA/RNA hybrids, and related molecules such as, polynucleotides or oligonucleotides complementary or having at least a 90% homology to the genes set forth in FIG. 2 or mRNA sequences or parts thereof, and polynucleotides or oligonucleotides that hybridize to the genes set forth in FIG. 2, mRNAs, or to polynucleotides that encode proteins of FIG. 2 or FIG. 3 or analogs or variants thereof; or to polynucleotides that encode proteins of fragments of a peptide of FIG. 2 or FIG. 3 such as set forth in Tables V to XVIII, Table XX, Tables XXIII to XXVI, or analogs or variants thereof; or to polynucleotides that encode fragments/subsequences of a peptide of FIG. 2 or FIG. 3 such as any 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, 170, 175, 180, 185, 190, 195, 200, 205, 210, 215, 220, 225, 230, 235, 240, 245, 250, 255, 260, 265, 270, 275, 280, 285, 290, 295, 300, 305, 310, 315, 320, 325, 330, 335, 340, 345, 350, 355, 360, 365, 370, 375, 380, 385, 390, 395, 400, 405, 410, 415, 420, 425, 430, 435, 440, 445, 450, 455, 460, 465, 470, 475, 480, 485, 490, 495, 500, 505, 510, 515, 520, 525, 530, 535, 540, 545, 550, 555, 560, 565, 570, 575, 580, 585, 590, 595, 600, 605, 610, 615, 620, 625, 630, 635, 640, 645, 650, 655, 660, 665, 670, 675, 680, 685, 690, 695, 700, 705, 710, 715, 720, 725, 730, 735, 740, 745, 750, 755, 760, 765, 770, 775, 780, 785, 790, 795, 800, 805, 810, 815, 820, 825, 830, 835, 840, 845, 850, 855, 860, 865, 870, 875, 880, 885, 890, 895, 900, 905, 910, 915, 920, 925, 930, 935, 940, 945, 950, 955, 960, 965, 970, 975, 980, 985, 990, 995, 1000, 1025, 1050, 1075, 1100, 1125, 1150, 1175, 1200, etc., or more contiguous amino acids of a peptide of FIG. 2 or 3, or an analog or variant thereof.

Also provided are means for isolating cDNAs and the genes encoding proteins set forth in FIG. 2. Recombinant DNA molecules containing genes of FIG. 2 polynucleotides, cells transformed or transduced with such molecules, and host-vector systems for the expression of the genes set forth in FIG. 2 products are also provided. The invention further provides antibodies that bind to the proteins set forth in FIG. 2 and polypeptide fragments thereof, including polyclonal and monoclonal antibodies, murine and other mammalian antibodies, chimeric antibodies, humanized and fully human antibodies, and antibodies labeled with a detectable marker or therapeutic agent. In certain embodiments there is a proviso that the entire nucleic acid sequence of the genes of FIG. 2 is not encoded and/or the entire amino acid sequence of the proteins of FIG. 2 is not prepared. In certain embodiments, the entire nucleic acid sequence of the genes of FIG. 2 is encoded and/or the entire amino acid sequence of the proteins of FIG. 2 is prepared, either of which are in respective human unit dose forms.

The invention further provides methods for detecting the presence and status of FIG. 2 polynucleotides and proteins in various biological samples, as well as methods for identifying cells that express the genes set forth in FIG. 2. A typical embodiment of this invention provides methods for monitoring the FIG. 2 gene products in a tissue or hematology sample having or suspected of having some form of growth dysregulation such as cancer.

The invention further provides various immunogenic or therapeutic compositions and strategies for treating cancers that express a gene set forth in FIG. 2 such as cancers of tissues listed in Table I, including therapies aimed at inhibiting the transcription, translation, processing or function of the genes of FIG. 2 as well as cancer vaccines. In one aspect, the invention provides compositions, and methods comprising them, for treating a cancer that expresses a gene set forth in FIG. 2 in a human subject wherein the composition comprises a carrier suitable for human use and a human unit dose of one or more than one agent that inhibits the production or function of a gene or proteins of FIG. 2. Preferably, the carrier is a uniquely for use in humans. In another aspect of the invention, the agent is a moiety that is immunoreactive with a protein of FIG. 2. Non-limiting examples of such moieties include, but are not limited to, antibodies (such as single chain, monoclonal, polyclonal, humanized, chimeric, or human antibodies), functional equivalents thereof (whether naturally occurring or synthetic), and combinations thereof. The antibodies can be conjugated to a diagnostic or therapeutic moiety. In another aspect, the agent is a small molecule as defined herein.

In another aspect, the agent comprises one or more than one peptide which comprises a cytotoxic T lymphocyte (CTL) epitope that binds an HLA class I molecule in a human to elicit a CTL response to a protein of FIG. 2 and/or one or more than one peptide which comprises a helper T lymphocyte (HTL) epitope which binds an HLA class II molecule in a human to elicit an HTL response. The peptides of the invention may be on the same or on one or more separate polypeptide molecules. In a further aspect of the invention, the agent comprises one or more than one nucleic acid molecule that expresses one or more than one of the CTL or HTL response stimulating peptides as described above. In yet another aspect of the invention, the one or more than one nucleic acid molecule may express a moiety that is immunologically reactive with a protein of FIG. 2 as described above. The one or more than one nucleic acid molecule may also be, or encodes, a molecule that inhibits production of a protein set forth in FIG. 2. Non-limiting examples of such molecules include, but are not limited to, those complementary to a nucleotide sequence essential for production of a protein of FIG. 2 (e.g. antisense sequences or molecules that form a triple helix with a nucleotide double helix essential for production of a protein set forth in FIG. 2) or a ribozyme effective to lyse mRNA (sense or antisense) encoded by a gene of FIG. 2.

Please note, to determine the starting position of any peptide set forth in Tables V-XVIII and Tables XXIII to XXVI (collectively HLA Peptide Tables) respective to its parental protein in FIG. 2 or FIG. 3, reference is made to its respective protein.

One embodiment of the invention comprises an HLA peptide, that occurs at least twice in Tables V-XVIII and XXIII to XXVI collectively, or an oligonucleotide that encodes the HLA peptide. Another embodiment of the invention comprises an HLA peptide that occurs at least twice in Tables V-XVIII, or an oligonucleotide that encodes the HLA peptide. Another embodiment of the invention comprises an HLA peptide that occurs at least twice in Tables XXIII to XXVI, or an oligonucleotide that encodes the HLA peptide. Another embodiment of the invention comprises an HLA peptide that occurs at least once in Tables V-XVIII and is embedded within at least one peptide in Tables XXIII to XXVI, or an oligonucleotide that encodes the HLA peptide.

Another embodiment of the invention is antibody epitopes which comprise a peptide region, or an oligonucleotide encoding the peptide region, that has one two, three, four, or five of the following characteristics:

-   -   i) a peptide region of at least 5 amino acids of a particular         peptide of FIG. 3, in any whole number increment up to the full         length of that protein in FIG. 3, that includes an amino acid         position having a value equal to or greater than 0.5, 0.6, 0.7,         0.8, 0.9, or having a value equal to 1.0, in the Hydrophilicity         profile of FIG. 5;     -   ii) a peptide region of at least 5 amino acids of a particular         peptide of FIG. 3, in any whole number increment up to the full         length of that protein in FIG. 3, that includes an amino acid         position having a value equal to or less than 0.5, 0.4, 0.3,         0.2, 0.1, or having a value equal to 0.0, in the Hydropathicity         profile of FIG. 6;     -   iii) a peptide region of at least 5 amino acids of a particular         peptide of FIG. 3, in any whole number increment up to the full         length of that protein in FIG. 3, that includes an amino acid         position having a value equal to or greater than 0.5, 0.6, 0.7,         0.8, 0.9, or having a value equal to 1.0, in the Percent         Accessible Residues profile of FIG. 7;     -   iv) a peptide region of at least 5 amino acids of a particular         peptide of FIG. 3, in any whole number increment up to the full         length of that protein in FIG. 3, that includes an amino acid         position having a value equal to or greater than 0.5, 0.6, 0.7,         0.8, 0.9, or having a value equal to 1.0, in the Average         Flexibility profile of FIG. 8; or     -   v) a peptide region of at least 5 amino acids of a particular         peptide of FIG. 3, in any whole number increment up to the full         length of that protein in FIG. 3, that includes an amino acid         position having a value equal to or greater than 0.5, 0.6, 0.7,         0.8, 0.9, or having a value equal to 1.0, in the Beta-turn         profile of FIG. 9.

BRIEF DESCRIPTION OF THE FIGURES

FIGS. 1A-1R. The SSH sequences of the invention.

FIGS. 2A.1-2R. Genes and respective encoded proteins of the invention.

FIGS. 3A.1-3R. Amino acid sequences of the invention.

FIG. 4. Nucleic acid sequence and protein alignments.

FIGS. 5A-5U. Hydrophilicity amino acid profile of the proteins set forth in FIG. 2 determined by computer algorithm sequence analysis using the method of Hopp and Woods (Hopp T. P., Woods K. R., 1981. Proc. Natl. Acad. Sci. U.S.A. 78:3824-3828).

FIGS. 6A-6U. Hydropathicity amino acid profile of the proteins set forth in FIG. 2 determined by computer algorithm sequence analysis using the method of Kyte and Doolittle (Kyte J., Doolittle R. F., 1982. J. Mol. Biol. 157:105-132).

FIGS. 7A-7U. Percent accessible residues amino acid profile of the proteins set forth in FIG. 2 determined by computer algorithm sequence analysis using the method of Janin (Janin J., 1979 Nature 277:491-492).

FIGS. 8A-8U. Average flexibility amino acid profile of the proteins set forth in FIG. 2 determined by computer algorithm sequence analysis using the method of Bhaskaran and Ponnuswamy (Bhaskaran R., and Ponnuswamy P. K., 1988. Int. J. Pept. Protein Res. 32:242-255).

FIGS. 9A-9U. Beta-turn amino acid profile of the proteins set forth in FIG. 2 determined by computer algorithm sequence analysis using the method of Deleage and Roux (Deleage, G., Roux B. 1987 Protein Engineering 1:289-294).

FIGS. 10A-10Z. Secondary structure predictions for the proteins set forth in FIG. 2. The sequence identifiers for the respective amino acids are as follows: 74P3B3 v1 (SEQ ID NO 689), 74P3B3 v2 (SEQ ID NO 690), 83P4B8 (SEQ ID NO 691), 109P1D4 (SEQ ID NO 692), 151P4E11 (SEQ ID NO 693), 151P1C7a (SEQ ID NO 694), 154P2A8 (SEQ ID NO 695), 156P1D4 (SEQ ID NO 696), 156P5C12 (SEQ ID NO 697), 159P2B5 (SEQ ID NO 698), 161P2B7a (SEQ ID NO 699), 179P3G7 (SEQ ID NO 700), 184P3C10B (SEQ ID NO 701), 184P3G10 (SEQ ID NO 702), 185P2C9 v1 (SEQ ID NO 703), 185P2C9 v2 (SEQ ID NO 704), 185P3C2 (SEQ ID NO 705), 186P1H9 (SEQ ID NO 706), 187P3F2 (SEQ ID NO 707), 192P2G7 (SEQ ID NO 708). The secondary structures of the proteins set forth in FIG. 2 were predicted using the HNN—Hierarchical Neural Network method. This method predicts the presence and location of alpha helices, extended strands, and random coils from the primary protein sequence. The percent of the protein in a given secondary structure is also listed for each variant.

Transmembrane predictions for the proteins set forth in FIG. 2. Schematic representations of the probability of existence of transmembrane regions and orientation of the proteins of FIG. 2 based on the TMpred algorithm of Hofmann and Stoffel which utilizes TMBASE (K. Hofmann, W. Stoffel. TMBASE—A database of membrane spanning protein segments Biol. Chem. Hoppe-Seyler 374:166, 1993). Schematic representation of the probability of the existence of transmembrane regions and the extracellular and intracellular orientation of the proteins of FIG. 2 based on the TMHMM algorithm of Sonnhammer, von Heijne, and Krogh (Erik L. L. Sonnhammer, Gunnar von Heijne, and Anders Krogh: A hidden Markov model for predicting transmembrane helices in protein sequences. In Proc. of Sixth Int. Conf. on Intelligent Systems for Molecular Biology, p 175-182 Ed J. Glasgow, T. Littlejohn, F. Major, R. Lathrop, D. Sankoff, and C. Sensen Menlo Park, Calif.: AAAI Press, 1998).

FIGS. 11 b, 11 c, 11 e, 11 j, 11 k, 11 m, 11 n, 11 o, and 11 r. The nucleotide sequences of transcript variants of the invention.

FIGS. 12 b, 12 c, 12 e, 12 j, 12 k, 12 m, 12 n, 12 o, and 12 r. These Figures show amino acid sequences of proteins translated from the corresponding transcript variants set forth in FIG. 11.

FIGS. 13 b, 13 c, 13 e, 13 j, 13 k, 13 m, 13 n, 13 o, and 13 r. These Figures display the alignment of the nucleotide sequences of respective transcript variants.

FIGS. 14 b, 14 c, 14 e, 14 j, 14 k, 14 m, 14 n, 14 o, and 14 r. These Figures display the alignment of the protein sequences from the respective transcript variants. The sub-numbering nomenclature of FIG. 11 through FIG. 14 is set forth in the following legend:

FIG. 11-14 Sub-part Target A 074P3B3 B 083P4B8 C 109P1D4 D 151P1C7A E 151P4E11 F 154P2A8 G 156P1D4 H 156P5C12 I 159P2B5 J 161P2B7a K 179P3G7 L 184P3C10B M 184P3G10 N 185P2C9 O 185P3C2 P 186P1H9 Q 187P3F2 R 192P2G7

FIG. 15. Expression of 74P3B3 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), two prostate metastasis to lymph node (LN) harvested from two different patients, prostate cancer pool, bladder cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 74P3B3, was performed at 26 and 30 cycles of amplification. Results show strong expression of 74P3B3 in the two prostate metastasis to LN specimens and in prostate cancer pool. Expression was also detected in bladder cancer pool, cancer metastasis pool, and vital pool 2 but not in the vital pool 1.

FIG. 16A-16C. Expression of 74P3B3 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 74P3B3 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 7 kB 74P3B3 transcript in prostate but not in the other normal tissues tested. Expression was also detected in LAPC-4AD and LAPC-4AI but not in LAPC-9AD and LAPC-9AI.

FIG. 17. Expression of 74P3B3 in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), pool of 3 prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 μg of total RNA/lane was probed with 74P3B3 SSH sequence. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 74P3B3 in normal prostate and in patient prostate cancer specimens.

FIG. 18. Expression of 74P3B3 in patient cancer specimens. Expression of 74P3B3 was assayed in a panel of human cancers (T) and their respective matched normal tissues (N) on RNA dot blots. Upregulated expression of 74P3B3 in tumors compared to normal tissues was observed in prostate, kidney, breast and colon tumors. The expression detected in normal adjacent tissues (isolated from diseased tissues) but not in normal tissues (isolated from healthy donors) may indicate that these tissues are not fully normal and that 74P3B3 may be expressed in early stage tumors.

FIG. 19. Expression of 83P4B8 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 83P4B8, was performed at 30 cycles of amplification. Results show strong expression of 83P4B8 in all cancer pools tested. Very low expression was detected in the vital pools.

FIG. 20A-20C. Expression of 83P4B8 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 83P4B8 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of two approximately 4.4 kb 83P4B8 transcripts in testis and to lower level in thymus but not in the other normal tissues tested. Expression was also detected in all 4 LAPC prostate cancer xenografts.

FIG. 21. Expression of 83P4B8 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three prostate cancers (PC), bladder cancers (BC), kidney cancers (KC), colon cancers (CC), lung cancers (LC), ovary cancers (OC), cancer metastasis (Met), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr) normal ovary (NO) and normal pancreas (NPa). Northern blot with 10 μg of total RNA/lane was probed with 83P4B8 sequence. Size standards in kilobases (kb) are indicated on the side. Results show expression of 83P4B8 in the bladder cancers and ovary cancers. Expression of 83P4B8 was also detected in prostate cancers, kidney cancers, colon cancers, lung cancers, cancer metastasis and pancreas cancer but not in the normal tissues tested.

FIG. 22. Expression of 83P4B8 in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 μg of total RNA/lane was probed with 83P4B8 SSH sequence. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 83P4B8 in the patient prostate cancer specimens.

FIG. 23. Expression of 83P4B8 in colon cancer patient specimens. RNA was extracted from colon cancer cell lines (CL), normal colon (N), colon cancer patient tumors (T) and their normal adjacent tissues (Nat). Northern blots with 10 μg of total RNA were probed with the 83P4B8 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 83P4B8 in the colon tumor tissues and in all three colon cancer cell lines tested, but not in the normal tissues.

FIG. 24. Expression of 109P1D4 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 109P1D4, was performed at 30 cycles of amplification. Results show strong expression of 109P1D4 in all cancer pools tested. Very low expression was detected in the vital pools

FIGS. 25A and 25B. Expression of 109P1D4 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 109P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 10 kb 109P1D4 transcript in ovary. Weak expression was also detected in placenta and brain, but not in the other normal tissues tested.

FIG. 26. Expression of 109P1D4 in human cancer cell lines. RNA was extracted from a number of human prostate and bone cancer cell lines. Northern blots with 10 μg of total RNA/lane were probed with the 109P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of 109P1D4 in LAPC-9AD, LAPC-9AI, LNCaP prostate cancer cell lines, and in the bone cancer cell lines, SK-ES-1 and RD-ES.

FIG. 27. Expression of 109P1D4 in patient cancer specimens. Expression of 109P1D4 was assayed in a panel of human cancers (T) and their respective matched normal tissues (N) on RNA dot blots. Upregulated expression of 109P1D4 in tumors compared to normal tissues was observed in uterus, lung and stomach. The expression detected in normal adjacent tissues (isolated from diseased tissues) but not in normal tissues (isolated from healthy donors) may indicate that these tissues are not fully normal and that 109P1D4 may be expressed in early stage tumors.

FIG. 28. Expression of 151P1C7A by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 151P1C7A, was performed at 26 and 30 cycles of amplification. Results show strong expression of 151P1C7A in bladder, lung, and metastasis cancer pools tested. Expression was also detected in xenograft, prostate, kidney and colon cancer pools but not in the vital pools.

FIGS. 29A and 29B. Expression of 151P1C7A in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 151P1C7A SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2 kb 151P1C7A transcript in placenta but not in the other normal tissues tested.

FIG. 30. Expression of 151P1C7A in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 151P1C7A SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 151P1C7A in patient bladder cancer tissues, and in all bladder cancer cell lines tested, but not in normal bladder.

FIG. 31. Expression of 151P1C7A in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 μg of total RNA/lane was probed with 151P1C7A SSH sequence. Size standards in kilobases (kb) are indicated on the side. Results show expression of 151P1C7A in the patient prostate cancer specimens.

FIG. 32. Expression of 151P4E11 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 151P4E11, was performed at 26 and 30 cycles of amplification. Results show strong expression of 151P4E11 in all cancer pools tested. Expression was detected in vital pool 2 but not in vital pool 1.

FIG. 33A-33C. Expression of 151P4E11 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 151P4E11 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 1.2 kb 151P4E11 transcript in prostate, testis, colon and small intestine. Expression was also detected in all the LAPC prostate cancer xenografts LAPC-4AD, LAPC-4AI, and LAPC-9AI, but not in LAPC-9AD.

FIG. 34. Expression of 154P2A8 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 154P2A8, was performed at 26 and 30 cycles of amplification. Results show strong expression of 154P2A8 in bladder cancer pool and lung cancer pool. Expression was also detected in prostate cancer pool, kidney cancer pool, colon cancer pool, and cancer metastasis pool but not in vital pool 1 and vital pool 2.

FIG. 35. Expression of 156P1D4 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 156P1D4, was performed at 26 and 30 cycles of amplification. Results show strong expression of 156P1D4 in kidney cancer pool and vital pool 1. Expression was also detected in xenograft pool, prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and vital pool 2.

FIG. 36. Expression of 156P1D4 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 156P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2 kb 156P1D4 transcript in kidney and prostate but not in the other normal tissues tested.

FIG. 37. Expression of 156P1D4 in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N). Northern blots with 10 μg of total RNA were probed with the 156P1D4 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 156P1D4 in all kidney tumor tissues tested. The expression of 156P1D4 detected in tumor tissues is stronger than in normal tissues.

FIG. 38. Expression of 156P5C12 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC -4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 156P5C12, was performed at 26 and 30 cycles of amplification. Results show strong expression of 156P5C12 in kidney cancer pool and vital pool 1. Expression was also detected in xenograft pool, prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and vital pool 2.

FIGS. 39A and 39B. Expression of 156P5C12 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 156P5C12 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 1.4 kb 156P5C12 transcript in kidney but not in the other normal tissues tested.

FIG. 40. Expression of 156P5C12 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, SW839), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT). Northern blots with 10 μg of total RNA were probed with the 156P5C12 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 156P5C12 in normal tissues, and in some but not all kidney tumor tissues. Expression was absent in the kidney cancer cell lines tested.

FIG. 41. Expression of 159P2B5 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), and bladder cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 159P2B5, was performed at 26 and 30 cycles of amplification. Results show expression of 159P2B5 in bladder cancer pool tested but not in the vital pools.

FIGS. 42A and 42B. Expression of 159P2B5 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 159P2B5 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show very weak expression of an approximately 4.5 kb 159P2B5 transcript in spleen, kidney and small intestine.

FIG. 43. Expression of 159P2B5 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (NB), and bladder cancer patient tumors (T) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 159P2B5 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 159P2B5 in patient bladder cancer tissues, and in the SCaBER bladder cancer cell line, but not in normal bladder, nor in the other cancer cell lines tested.

FIG. 44. Expression of 161P2B7A by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate metastasis to lymph node (LN), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 161P2B7A, was performed at 26 and 30 cycles of amplification. Results show strong expression of 161P2B7A in lung cancer pool and pancreas cancer pool. Expression was also detected in prostate metastasis to LN, prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Very low expression was observed in vital pool 2 but not in vital pool 1.

FIGS. 45A and 45B. Expression of 161P2B7A in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 161P2B7A SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show very low expression of 161P2B7A in testis but not in the other normal tissues tested.

FIG. 46. Expression of 161P2B7A in Multiple Normal Tissues. An mRNA dot blot containing 76 different samples from human tissues was analyzed using a 161P2B7A SSH probe. Expression was not detected in any of the 76 normal tissues tested. The positive genomic DNA control showed very strong signal confirming the validity of the experiment.

FIG. 47. Expression of 161P2B7A in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 161P2B7A SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of two 161P2B7A transcripts, approximately 1.2 and 7 kb, in kidney cancer specimens but not in normal kidney.

FIG. 48. Expression of 161P2B7A in lung cancer patient specimens. RNA was extracted from lung cancer cell lines (CL), normal lung, lung tumors (T), and their normal adjacent tissues (NAT) isolated from lung cancer patients. Northern blot with 10 μg of total RNA/lane was probed with the 161P2B7A fragment. Size standards in kilobases (kb) are indicated on the side. The results show expression of 161P2B7A in the lung tumors, but not in normal lung tissues. Expression was also detected in the lung cancer cell lines CALU-1, A427 and NCI-146 but not in the small cell lung cancer cell line NCI-H82.

FIG. 49. Expression of 161P2B7A in pancreas and ovary cancer patient specimens. RNA was extracted from normal pancreas (NPa), pancreas cancer (PC), normal ovary (NO), and ovary cancer patient specimen (OC). Northern blot with 10 μg of total RNA/lane was probed with the 161P2B7A fragment. Size standards in kilobases (kb) are indicated on the side. The results show expression of 161P2B7A in the pancreas and ovary cancer patient specimens, but not in the normal tissues.

FIG. 50. Expression of 179P3G7 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), bladder cancer pool, kidney cancer pool, lung cancer pool, breast cancer pool, cancer metastasis pool, pancreas cancer pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 179P3G7, was performed at 26 and 30 cycles of amplification. Results show strong expression of 179P3G7 in kidney cancer pool and breast cancer pool. Expression was also detected in bladder cancer pool, lung cancer pool, cancer metastasis pool, pancreas cancer pool and prostate metastasis to LN, and vital pool 1, but not in vital pool 2.

FIGS. 51A and 51B. Expression of 179P3G7 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 179P3G7 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of 179P3G7 strongly in skeletal muscle, and weakly in kidney, liver and heart but not in the other normal tissues tested.

FIG. 52. Expression of 179P3G7 in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 179P3G7 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 179P3G7 in kidney cancer specimens. Expression of 179P3G7 is stronger in kidney tumors compared to normal kidney tissues.

FIG. 53. Expression of 184P3C10B by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 184P3C10B, was performed at 26 and 30 cycles of amplification. Results show expression of 184P3C10B in xenograft pool, prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, and cancer metastasis pool. Expression was also detected in vital pool 2 but at a much lower level in vital pool 1.

FIG. 54. Expression of 184P3C10B in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 184P3C10B SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 2.4 and 5 kb 184P3C10B transcripts in placenta and to lower level in colon and small intestine, but not in the other normal tissues tested.

FIG. 55. Expression of 184P3C10B in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 184P3C10B SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 184P3C10B in patient bladder cancer tissues, and in the bladder cancer cell line SCaBER, but not in normal bladder nor in the other bladder cancer cell lines tested.

FIG. 56. Expression of 184P3G10 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), bladder cancer pool, kidney cancer pool, colon cancer pool, and lung cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 184P3G10, was performed at 26 and 30 cycles of amplification. Results show strong expression of 184P3G10 in bladder cancer pool, kidney cancer pool, and colon cancer pool. Expression was also detected in xenograft pool, lung cancer pool, vital pool 2 but not in vital pool 1.

FIGS. 57A and 57B. Expression of 184P3G10 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 184P3G10 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of two approximately 4.4 kb 184P3G10 transcripts in colon and small intestine, but not in the other normal tissues tested.

FIG. 58. Expression of 184P3G10 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three bladder cancers, colon cancers, lung cancers, breast cancers, ovary cancers, cancer metastasis, as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK). Northern blot with 10 μg of total RNA/lane was probed with 184P3G10 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 184P3G10 in the bladder cancers, colon cancers and ovary cancers. Expression of 184P3G10 was also detected in lung cancers, breast cancers, and cancer metastasis but not in the normal tissues tested.

FIG. 59. Expression of 184P3G10 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (N), bladder cancer patient tumors (T) and their normal adjacent tissue (Nat) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 184P3G10 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 184P3G10 in patient bladder cancer tissues, but not in normal bladder nor in the bladder cancer cell lines tested.

FIG. 60. Expression of 185P2C9 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate metastasis to lymph node (LN), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 185P2C9, was performed at 30 cycles of amplification. Results show strong expression of 185P2C9 in bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool and pancreas cancer pool. Expression was also detected in prostate metastasis to LN, prostate cancer pool, kidney cancer pool, breast cancer pool, cancer metastasis pool, vital pool 2 but not in vital pool 1.

FIG. 61. Expression of 185P2C9 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 185P2C9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of and approximately 8.5 kb 185P2C9 transcript in testis and brain, but not in the other normal tissues tested.

FIG. 62. Expression of 185P2C9 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, 382, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 185P2C9 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 185P2C9 in bladder cancer patient tissues, and in the bladder cancer cell lines tested. Expression of 185P2C9 is significantly stronger in bladder tumor tissues compared to normal tissues.

FIG. 63. Expression of 185P2C9 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, Caki-1), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 185P2C9 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 185P2C9 in kidney cancer specimens and kidney cancer cell lines, but not in normal kidney.

FIG. 64. Expression of 186P1H9 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, cancer metastasis pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 186P1H9, was performed at 26 and 30 cycles of amplification. Results show strong expression of 186P1H9 in kidney cancer pool, colon cancer pool, ovary cancer pool, cancer metastasis pool, and pancreas cancer pool. Expression was also detected in bladder cancer pool, lung cancer pool, vital pool 2 but not in vital pool 1.

FIG. 65. Expression of 186P1H9 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 186P1H9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2.6 kb 186P1H9 transcript in testis, spleen, pancreas and brain. Lower expression is also detected in heart, skeletal muscle, prostate, colon and small intestine.

FIG. 66. Expression of 186P1H9 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three kidney cancers (KC), ovary cancers (OC), cancer metastasis (Met), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr), normal ovary (NO), and normal pancreas (NPa). Northern blot with 10 μg of total RNA/lane was probed with 186P1H9 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 186P1H9 in the bladder cancers, ovary cancers, cancer metastasis and pancreas cancers, but not in normal tissues. Expression of 186P1H9 is significantly stronger in patient cancer tissues compared to normal tissues.

FIG. 67. Expression of 186P1H9 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, Caki-1), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 186P1H9 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 186P1H9 in kidney cancer patient specimens, but not in normal kidney, nor in the kidney cancer cell lines.

FIG. 68. Expression of 186P1H9 in ovarian and testicular cancer patient specimens. RNA was extracted from normal ovary (NO), ovary cancer patient specimens (P1, P2, P3), normal testis (NTe), and testis cancer patient specimens (P4, P5, P6). Northern blot with 10 μg of total RNA/lane was probed with the 186P1H9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 186P1H9 in the ovary cancer patient specimens, but not in the normal ovary. Expression was also detected in normal and in testis cancer specimens.

FIG. 69. Expression of 187P3F2 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), kidney cancer pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 187P3F2, was performed at 26 and 30 cycles of amplification. Results show strong expression of 187P3F2 in kidney cancer pool, pancreas cancer pool and vital pool 1, but not in vital pool 2.

FIG. 70. Expression of 187P3F2 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 187P3F2 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an 4.5 kb 187P3F2 transcript in kidney and brain, but not in the other tissues tested.

FIG. 71. Expression of 187P3F2 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three kidney cancers (KC), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr), normal ovary (NO), and normal pancreas (NPa). Northern blot with 10 μg of total RNA/lane was probed with 187P3F2 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 187P3F2 in kidney cancers, pancreas cancers, and normal kidney, but not in the other normal tissues.

FIG. 72. Expression of 187P3F2 in pancreas cancer patient specimens. RNA was extracted from pancreas cancer cell lines (CL), normal pancreas (N), and pancreas tumor tissues (T) isolated from pancreatic cancer patients. Northern blot with 10 μg of total RNA/lane was probed with the 187P3F2 SSH fragment. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 187P3F2 in the pancreas cancer specimens, but not in normal pancreas nor in the cancer cell lines tested.

FIG. 73. Expression of 192P2G7 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, pancreas cancer pool, and prostate metastasis to lymph node (LN). Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 186P1H9, was performed at 26 and 30 cycles of amplification. Results show strong expression of 186P1H9 in pancreas cancer pool and prostate metastasis to LN. Expression was also detected in prostate cancer pool, bladder cancer pool, kidney cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, vital pool 2 but not in vital pool 1.

FIG. 74. Expression of 185P3C2 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), and bladder cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 185P3C2, was performed at 26 and 30 cycles of amplification. Results show strong expression of 185P3C2 in bladder cancer pool. Low level expression was detected in vital pool 2, but not in vital pool 1.

DETAILED DESCRIPTION OF THE INVENTION

Outline of Sections

-   -   I.) Definitions     -   II.) Polynucleotides of the Invention         -   II.A.) Uses Polynucleotides of the Invention             -   II.A.1.) Monitoring of Genetic Abnormalities             -   II.A.2.) Antisense Embodiments             -   II.A.3.) Primers and Primer Pairs             -   II.A.4.) Isolation of Nucleic Acid Molecules that Encode                 Proteins of the Invention             -   II.A.5.) Recombinant Nucleic Acid Molecules and                 Host-Vector Systems     -   III.) Proteins of the Invention         -   III.A.) Motif-bearing Protein Embodiments         -   III.B.) Expression of FIG. 2–related Proteins         -   III.C.) Modifications of FIG. 2–related Proteins         -   III.D.) Uses of FIG. 2–related Proteins     -   IV.) Antibodies of the Invention     -   V.) Cellular Immune Responses of the Invention     -   VI.) Transgenic Animals of the Invention     -   VII.) Methods for the Detection of a Gene or Protein of the         Invention     -   VIII.) Methods for Monitoring the Status of Genes and Proteins         of the Invention     -   IX.) Identification of Molecules That Interact With the Proteins         of FIG. 2     -   X.) Therapeutic Methods and Compositions         -   X.A.) Anti-Cancer Vaccines         -   X.B.) A Protein of FIG. 2 as a Target for Antibody-Based             Therapy         -   X.C.) A Protein of FIG. 2 as a Target for Cellular Immune             Responses             -   X.C.1. Minigene Vaccines             -   X.C.2. Combinations of CTL Peptides with Helper Peptides             -   X.C.3. Combinations of CTL Peptides with T Cell Priming                 Agents             -   X.C.4. Vaccine Compositions Comprising DC Pulsed with                 CTL and/or HTL Peptides         -   X.D.) Adoptive Immunotherapy         -   X.E.) Administration of Vaccines for Therapeutic or             Prophylactic Purposes     -   XI.) Diagnostic and Prognostic Embodiments of the Invention     -   XII.) Inhibition of the Function of a Protein of the Invention         -   XII.A.) Inhibition of a Protein of FIG. 2 with Intracellular             Antibodies         -   XII.B.) Inhibition of a Protein of FIG. 2 with Recombinant             Proteins         -   XII.C.) Inhibition of Transcription or Translation in             Accordance with the Invention         -   XII.D.) General Considerations for Therapeutic Strategies     -   XII.) KITS

I.) Definitions:

Unless otherwise defined, all terms of art, notations and other scientific terms or terminology used herein are intended to have the meanings commonly understood by those of skill in the art to which this invention pertains. In some cases, terms with commonly understood meanings are defined herein for clarity and/or for ready reference, and the inclusion of such definitions herein should not necessarily be construed to represent a substantial difference over what is generally understood in the art. Many of the techniques and procedures described or referenced herein are well understood and commonly employed using conventional methodology by those skilled in the art, such as, for example, the widely utilized molecular cloning methodologies described in Sambrook et al., Molecular Cloning: A Laboratory Manual 2nd. edition (1989) Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. As appropriate, procedures involving the use of commercially available kits and reagents are generally carried out in accordance with manufacturer defined protocols and/or parameters unless otherwise noted.

The terms “advanced prostate cancer”, “locally advanced prostate cancer”, “advanced disease” and “locally advanced disease” mean prostate cancers that have extended through the prostate capsule, and are meant to include stage C disease under the American Urological Association (AUA) system, stage C1-C2 disease under the Whitmore-Jewett system, and stage T3-T4 and N+ disease under the TNM (tumor, node, metastasis) system. In general, surgery is not recommended for patients with locally advanced disease, and these patients have substantially less favorable outcomes compared to patients having clinically localized (organ-confined) prostate cancer. Locally advanced disease is clinically identified by palpable evidence of induration beyond the lateral border of the prostate, or asymmetry or induration above the prostate base. Locally advanced prostate cancer is presently diagnosed pathologically following radical prostatectomy if the tumor invades or penetrates the prostatic capsule, extends into the surgical margin, or invades the seminal vesicles.

“Altering the native glycosylation pattern” is intended for purposes herein to mean deleting one or more carbohydrate moieties found in native sequence of the genes set forth in FIG. 2 (either by removing the underlying glycosylation site or by deleting the glycosylation by chemical and/or enzymatic means), and/or adding one or more glycosylation sites that are not present in the native sequence of a protein set forth in FIG. 2. In addition, the phrase includes qualitative changes in the glycosylation of the native proteins, involving a change in the nature and proportions of the various carbohydrate moieties present.

The term “analog” refers to a molecule which is structurally similar or shares similar or corresponding attributes with another molecule (e.g. a protein of FIG. 2). For example an analog of a protein of FIG. 2 can be specifically bound by an antibody or T cell that specifically binds to the respective protein of FIG. 2.

The term “antibody” is used in the broadest sense. Therefore an “antibody” can be naturally occurring or man-made such as monoclonal antibodies produced by conventional hybridoma technology. Antibodies of the invention comprise monoclonal and polyclonal antibodies as well as fragments containing the antigen-binding domain and/or one or more complementarity determining regions of these antibodies that specifically bind a protein of FIG. 2.

An “antibody fragment” is defined as at least a portion of the variable region of the immunoglobulin molecule that binds to its target, i.e., the antigen-binding region. In one embodiment it specifically covers single antibodies and clones thereof (including agonist, antagonist and neutralizing antibodies) and antibody compositions with polyepitopic specificity.

The term “codon optimized sequences” refers to nucleotide sequences that have been optimized for a particular host species by replacing any codons having a usage frequency of less than about 20%. Nucleotide sequences that have been optimized for expression in a given host species by elimination of spurious polyadenylation sequences, elimination of exon/intron splicing signals, elimination of transposon-like repeats and/or optimization of GC content in addition to codon optimization are referred to herein as an “expression enhanced sequences.”

The term “cytotoxic agent” refers to a substance that inhibits or prevents the expression activity of cells, function of cells and/or causes destruction of cells. The term is intended to include radioactive isotopes chemotherapeutic agents, and toxins such as small molecule toxins or enzymatically active toxins of bacterial, fungal, plant or animal origin, including fragments and/or variants thereof. Examples of cytotoxic agents include, but are not limited to maytansinoids, yttrium, bismuth, ricin, ricin A-chain, doxorubicin, daunorubicin, taxol, ethidium bromide, mitomycin, etoposide, tenoposide, vincristine, vinblastine, colchicine, dihydroxy anthracin dione, actinomycin, diphtheria toxin, Pseudomonas exotoxin (PE) A, PE40, abrin, abrin A chain, modeccin A chain, alpha-sarcin, gelonin, mitogellin, retstrictocin, phenomycin, enomycin, curicin, crotin, calicheamicin, sapaonaria officinalis inhibitor, and glucocorticoid and other chemotherapeutic agents, as well as radioisotopes such as At²¹¹, I¹³¹, I¹²⁵, Y⁹⁰, Re¹⁸⁶, Re¹⁸⁸, Sm¹⁵³, Bi²¹², P³² and radioactive isotopes of Lu. Antibodies may also be conjugated to an anti-cancer pro-drug activating enzyme capable of converting the pro-drug to its active form.

The term “homolog” refers to a molecule which exhibits homology to another molecule, by for example, having sequences of chemical residues that are the same or similar at corresponding positions.

“Human Leukocyte Antigen” or “HLA” is a human class I or class II Major Histocompatibility Complex (MHC) protein (see, e.g., Stites, et al., IMMUNOLOGY, 8^(TH) ED., Lange Publishing, Los Altos, Calif. (1994).

The terms “hybridize”, “hybridizing”, “hybridizes” and the like, used in the context of polynucleotides, are meant to refer to conventional hybridization conditions, preferably such as hybridization in 50% formamide/6×SSC/0.1% SDS/100 μg/ml ssDNA, in which temperatures for hybridization are above 37 degrees C. and temperatures for washing in 0.1×SSC/0.1% SDS are above 55 degrees C.

The phrases “isolated” or “biologically pure” refer to material which is substantially or essentially free from components which normally accompany the material as it is found in its native state. Thus, isolated peptides in accordance with the invention preferably do not contain materials normally associated with the peptides in their in situ environment. For example, a polynucleotide is said to be “isolated” when it is substantially separated from contaminant polynucleotides that correspond or are complementary to genes other than the genes of FIG. 2 or that encode polypeptides other than proteins of FIG. 2 product or fragments thereof. A skilled artisan can readily employ nucleic acid isolation procedures to obtain an isolated polynucleotide. A protein is said to be “isolated,” for example, when physical, mechanical or chemical methods are employed to remove a protein of FIG. 2 from cellular constituents that are normally associated with the protein. A skilled artisan can readily employ standard purification methods to obtain an isolated FIG. 2 protein. Alternatively, an isolated protein can be prepared by chemical means.

The term “mammal” refers to any organism classified as a mammal, including mice, rats, rabbits, dogs, cats, cows, horses and humans. In one embodiment of the invention, the mammal is a mouse. In another embodiment of the invention, the mammal is a human.

The terms “metastatic prostate cancer” and “metastatic disease” mean prostate cancers that have spread to regional lymph nodes or to distant sites, and are meant to include stage D disease under the AUA system and stage TxNxM+ under the TNM system. As is the case with locally advanced prostate cancer, surgery is generally not indicated for patients with metastatic disease, and hormonal (androgen ablation) therapy is a preferred treatment modality. Patients with metastatic prostate cancer eventually develop an androgen-refractory state within 12 to 18 months of treatment initiation. Approximately half of these androgen-refractory patients die within 6 months after developing that status. The most common site for prostate cancer metastasis is bone. Prostate cancer bone metastases are often osteoblastic rather than osteolytic (i.e., resulting in net bone formation). Bone metastases are found most frequently in the spine, followed by the femur, pelvis, rib cage, skull and humerus. Other common sites for metastasis include lymph nodes, lung, liver and brain. Metastatic prostate cancer is typically diagnosed by open or laparoscopic pelvic lymphadenectomy, whole body radionuclide scans, skeletal radiography, and/or bone lesion biopsy.

The term “monoclonal antibody” refers to an antibody obtained from a population of substantially homogeneous antibodies, i.e., the antibodies comprising the population are identical except for possible naturally occurring mutations that are present in minor amounts.

A “motif”, as in biological motif of a FIG. 2–related protein, refers to any pattern of amino acids forming part of the primary sequence of a protein, that is associated with a particular function (e.g. protein-protein interaction, protein-DNA interaction, etc) or modification (e.g. that is phosphorylated, glycosylated or amidated), or localization (e.g. secretory sequence, nuclear localization sequence, etc.) or a sequence that is correlated with being immunogenic, either humorally or cellularly. A motif can be either contiguous or capable of being aligned to certain positions that are generally correlated with a certain function or property. In the context of HLA motifs, “motif” refers to the pattern of residues in a peptide of defined length, usually a peptide of from about 8 to about 13 amino acids for a class I HLA motif and from about 6 to about 25 amino acids for a class II HLA motif, which is recognized by a particular HLA molecule. Peptide motifs for HLA binding are typically different for each protein encoded by each human HLA allele and differ in the pattern of the primary and secondary anchor residues.

A “pharmaceutical excipient” comprises a material such as an adjuvant, a carrier, pH-adjusting and buffering agents, tonicity adjusting agents, wetting agents, preservative, and the like.

“Pharmaceutically acceptable” refers to a non-toxic, inert, and/or composition that is physiologically compatible with humans or other mammals.

The term “polynucleotide” means a polymeric form of nucleotides of at least 10 bases or base pairs in length, either ribonucleotides or deoxynucleotides or a modified form of either type of nucleotide, and is meant to include single and double stranded forms of DNA and/or RNA. In the art, this term if often used interchangeably with “oligonucleotide”. A polynucleotide can comprise a nucleotide sequence disclosed herein wherein thymine (T), as shown for example in FIG. 2, can also be uracil (U); this definition pertains to the differences between the chemical structures of DNA and RNA, in particular the observation that one of the four major bases in RNA is uracil (U) instead of thymine (T).

The term “polypeptide” means a polymer of at least about 4, 5, 6, 7, or 8 amino acids. Throughout the specification, standard three letter or single letter designations for amino acids are used. In the art, this term is often used interchangeably with “peptide” or “protein”.

An HLA “primary anchor residue” is an amino acid at a specific position along a peptide sequence which is understood to provide a contact point between the immunogenic peptide and the HLA molecule. One to three, usually two, primary anchor residues within a peptide of defined length generally defines a “motif” for an immunogenic peptide. These residues are understood to fit in close contact with peptide binding groove of an HLA molecule, with their side chains buried in specific pockets of the binding groove. In one embodiment, for example, the primary anchor residues for an HLA class I molecule are located at position 2 (from the amino terminal position) and at the carboxyl terminal position of a 8, 9, 10, 11, or 12 residue peptide epitope in accordance with the invention. In another embodiment, for example, the primary anchor residues of a peptide that will bind an HLA class II molecule are spaced relative to each other, rather than to the termini of a peptide, where the peptide is generally of at least 9 amino acids in length. The primary anchor positions for each motif and supermotif are set forth in Table IV. For example, analog peptides can be created by altering the presence or absence of particular residues in the primary and/or secondary anchor positions shown in Table IV. Such analogs are used to modulate the binding affinity and/or population coverage of a peptide comprising a particular HLA motif or supermotif

A “recombinant” DNA or RNA molecule is a DNA or RNA molecule that has been subjected to molecular manipulation in vitro.

Non-limiting examples of small molecules include compounds that bind or interact with the proteins of FIG. 2; ligands including hormones, neuropeptides, chemokines, odorants, phospholipids, and functional equivalents thereof that bind and preferably inhibit function of a FIG. 2 protein. Such non-limiting small molecules preferably have a molecular weight of less than about 10 kDa, more preferably below about 9, about 8, about 7, about 6, about 5 or about 4 kDa. In certain embodiments, small molecules physically associate with, or bind, a FIG. 2 protein; and are not found in naturally occurring metabolic pathways; and/or are more soluble in aqueous than non-aqueous solutions

“Stringency” of hybridization reactions is readily determinable by one of ordinary skill in the art, and generally is an empirical calculation dependent upon probe length, washing temperature, and salt concentration. In general, longer probes require higher temperatures for proper annealing, while shorter probes need lower temperatures. Hybridization generally depends on the ability of denatured nucleic acid sequences to reanneal when complementary strands are present in an environment below their melting temperature. The higher the degree of desired homology between the probe and hybridizable sequence, the higher the relative temperature that can be used. As a result, it follows that higher relative temperatures would tend to make the reaction conditions more stringent, while lower temperatures less so. For additional details and explanation of stringency of hybridization reactions, see Ausubel et al., Current Protocols in Molecular Biology, Wiley Interscience Publishers, (1995).

“Stringent conditions” or “high stringency conditions”, as defined herein, are identified by, but not limited to, those that: (1) employ low ionic strength and high temperature for washing, for example 0.015 M sodium chloride/0.0015 M sodium citrate/0.1% sodium dodecyl sulfate at 50° C.; (2) employ during hybridization a denaturing agent, such as formamide, for example, 50% (v/v) formamide with 0.1% bovine serum albumin/0.1% Ficoll/0.1% polyvinylpyrrolidone/50 mM sodium phosphate buffer at pH 6.5 with 750 mM sodium chloride, 75 mM sodium citrate at 42° C.; or (3) employ 50% formamide, 5×SSC (0.75 M NaCl, 0.075 M sodium citrate), 50 mM sodium phosphate (pH 6.8), 0.1% sodium pyrophosphate, 5× Denhardt's solution, sonicated salmon sperm DNA (50 μg/ml), 0.1% SDS, and 10% dextran sulfate at 42° C., with washes at 42° C. in 0.2×SSC (sodium chloride/sodium. citrate) and 50% formamide at 55° C., followed by a high-stringency wash consisting of 0.1×SSC containing EDTA at 55° C. “Moderately stringent conditions” are described by, but not limited to, those in Sambrook et al., Molecular Cloning: A Laboratory Manual, New York: Cold Spring Harbor Press, 1989, and include the use of washing solution and hybridization conditions (e.g., temperature, ionic strength and % SDS) less stringent than those described above. An example of moderately stringent conditions is overnight incubation at 37° C. in a solution comprising: 20% formamide, 5×SSC (150 mM NaCl, 15 mM trisodium citrate), 50 mM sodium phosphate (pH 7.6), 5× Denhardt's solution, 10% dextran sulfate, and 20 mg/mL denatured sheared salmon sperm DNA, followed by washing the filters in 1×SSC at about 37-50° C. The skilled artisan will recognize how to adjust the temperature, ionic strength, etc. as necessary to accommodate factors such as probe length and the like.

An HLA “supermotif” is a peptide binding specificity shared by HLA molecules encoded by two or more HLA alleles.

As used herein “to treat” or “therapeutic” and grammatically related terms, refer to any improvement of any consequence of disease, such as prolonged survival, less morbidity, and/or a lessening of side effects which are the byproducts of an alternative therapeutic modality; full eradication of disease is not required.

A “transgenic animal” (e.g., a mouse or rat) is an animal having cells that contain a transgene, which transgene was introduced into the animal or an ancestor of the animal at a prenatal, e.g., an embryonic stage. A “transgene” is a DNA that is integrated into the genome of a cell from which a transgenic animal develops.

As used herein, an HLA or cellular immune response “vaccine” is a composition that contains or encodes one or more peptides of the invention. There are numerous embodiments of such vaccines, such as a cocktail of one or more individual peptides; one or more peptides of the invention comprised by a polyepitopic peptide; or nucleic acids that encode such individual peptides or polypeptides, erg., a minigene that encodes a polyepitopic peptide. The “one or more peptides” can include any whole unit integer from 1-150 or more, e.g., at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, or 150 or more peptides of the invention. The peptides or polypeptides can optionally be modified, such as by lipidation, addition of targeting or other sequences. HLA class I peptides of the invention can be admixed with, or linked to, HLA class II peptides, to facilitate activation of both cytotoxic T lymphocytes and helper T lymphocytes. HLA vaccines can also comprise peptide-pulsed antigen presenting cells, e.g., dendritic cells.

The term “variant” refers to a molecule that exhibits a variation from a described type or norm, such as a protein that has one or more different amino acid residues in the corresponding position(s) of a specifically described protein (e.g. a protein of FIG. 2 protein shown in FIG. 2 or FIG. 3. An analog is an example of a variant protein. Splice isoforms and single nucleotides polymorphisms (SNPs) are further examples of variants.

The “genes of FIG. 2–related proteins” of the invention include those specifically identified herein, as well as allelic variants, conservative substitution variants, analogs and homologs that can be isolated/generated and characterized without undue experimentation following the methods outlined herein or readily available in the art. Fusion proteins that combine parts of different genes set forth in FIG. 2 proteins of the invention or fragments thereof, as well as fusion proteins of a gene of FIG. 2 protein and a heterologous polypeptide are also included. Such genes of FIG. 2 proteins are collectively referred to as the genes of FIG. 2–related proteins, the proteins of the invention, or proteins of FIG. 2. The term “genes of FIG. 2–related protein” refers to a polypeptide fragment or a FIG. 2 protein sequence of 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, or more than 25 amino acids; or, at least 30, 35, 40, 45, 50, 55, 60, 65, 70, 80, 85, 90, 95, 100 or more than 100 amino acids. In certain cases the phrase “corresponding to” or “respective” is used instead of the term “-related.”

II.) Polynucleotides of the Invention

One aspect of the invention provides polynucleotides corresponding or complementary to all or part of: a gene of FIG. 2; gene of FIG. 2–related mRNA, a coding sequence of a gene of FIG. 2, an open reading frame of a gene of FIG. 2, each of the foregoing preferably in isolated form. Polynucleotides of the invention include polynucleotides encoding FIG. 2–related proteins and fragments thereof, DNA, RNA, DNA/RNA hybrid, and related molecules, polynucleotides or oligonucleotides complementary to a FIG. 2 gene or mRNA sequence or a part thereof, and polynucleotides or oligonucleotides that hybridize to a FIG. 2 gene, mRNA, or to a FIG. 2 encoding polynucleotide (collectively, “FIG. 2 polynucleotides”). In all instances when referred to in this section, T can also be U in FIG. 2.

Embodiments of a FIG. 2 polynucleotide include: a FIG. 2 polynucleotide having the sequence shown in FIG. 2, the nucleotide sequence of the genes of FIG. 2 as shown in FIG. 2 wherein T is U; at least 10 contiguous nucleotides of a polynucleotide having the sequence as shown in FIG. 2; or, at least 10 contiguous nucleotides of a polynucleotide having the sequence as shown in FIG. 2 where T is U. For example, embodiments of the FIG. 2 nucleotides comprise, without limitation:

(1) a polynucleotide comprising, consisting essentially of, or consisting of a sequence as shown in FIG. 2, wherein T can also be U;

(2) a polynucleotide comprising, consisting essentially of, or consisting of a sequence as shown in FIG. 2, from the first nucleotide residue of a reading frame through the last nucleotide residue of that reading frame, optionally followed by a stop codon, wherein T can also be U;

(3) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2A.1, from nucleotide residue number 289 through nucleotide residue number 828, optionally followed by a stop codon, wherein T can also be U;

(4) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2A.2, from nucleotide residue number 756 through nucleotide residue number 1439, optionally followed by a stop codon, wherein T can also be U;

(5) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2B, from nucleotide residue number 25 through nucleotide residue number 4008, optionally followed by a stop codon, wherein T can also be U;

(6) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2C, from nucleotide residue number 846 through nucleotide residue number 3908, optionally followed by a stop codon, wherein T can also be U;

(7) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2D, from nucleotide residue number 103 through nucleotide residue number 900, optionally followed by a stop codon, wherein T can also be U;

(8) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2E, from nucleotide residue number 3 through nucleotide residue number 371, optionally followed by a stop codon, wherein T can also be U;

(9) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2F, from nucleotide residue number 250 through nucleotide residue number 1323, optionally followed by a stop codon, wherein T can also be U;

(10) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2G, from nucleotide residue number 24 through nucleotide residue number 599, optionally followed by a stop codon, wherein T can also be U;

(11) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2H, from nucleotide residue number 178 through nucleotide residue number 858, optionally followed by a stop codon, wherein T can also be U;

(12) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 21, from nucleotide residue number 1517 through nucleotide residue number 2188, optionally followed by a stop codon, wherein T can also be U;

(13) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2J, from nucleotide residue number 198 through nucleotide residue number 767, optionally followed by a stop codon, wherein T can also be U;

(14) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2K, from nucleotide residue number 72 through nucleotide residue number 1097, optionally followed by a stop codon, wherein T can also be U;

(15) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2L, from nucleotide residue number 118 through nucleotide residue number 1233, optionally followed by a stop codon, wherein T can also be U;

(16) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2M, from nucleotide residue number 14 through nucleotide residue number 2257, optionally followed by a stop codon, wherein T can also be U;

(17) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2N.1, from nucleotide residue number 140 through nucleotide residue number 4060, optionally followed by a stop codon, wherein T can also be U;

(18) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2N.2, from nucleotide residue number 140 through nucleotide residue number 3565, optionally followed by a stop codon, wherein T can also be U;

(19) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2N.3, from nucleotide residue number 140 through nucleotide residue number 4075, optionally followed by a stop codon, wherein T can also be U;

(20) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2O, from nucleotide residue number 3 through nucleotide residue number 1655, optionally followed by a stop codon, wherein T can also be U;

(21) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2P, from nucleotide residue number 170 through nucleotide residue number 1459, optionally followed by a stop codon, wherein T can also be U;

(22) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2Q, from nucleotide residue number 60 through nucleotide residue number 1559, optionally followed by a stop codon, wherein T can also be U;

(23) a polynucleotide comprising, consisting essentially of, or consisting of the sequence as shown in FIG. 2R, from nucleotide residue number 84 through nucleotide residue number 938, optionally followed by a stop codon, wherein T can also be U;

(24) a polynucleotide that encodes a FIG. 2–related protein that is at least 90% homologous to an entire amino acid sequence shown in FIG. 2A-R;

(25) a polynucleotide that encodes a FIG. 2–related protein that is at least 90% identical to an entire amino acid sequence shown in FIG. 2A-R;

(26) a polynucleotide that encodes at least one peptide set forth in Tables V-XVIII, Table XX, or Tables XXIII to XXVI;

(27) a polynucleotide that encodes a peptide region of at least five amino acids of a peptide of FIG. 3 in any whole number increment up to the entire length of that protein, that includes an amino acid position having a value greater than 0.5 in the Hydrophilicity profile of FIG. 5 for that protein;

(28) a polynucleotide that encodes a peptide region of at least five amino acids of a peptide of FIG. 3 in any whole number increment up to the entire length of the protein, that includes an amino acid position having a value less than 0.5 in the Hydropathicity profile of FIG. 6 for that protein;

(29) a polynucleotide that encodes a peptide region of at least five amino acids of a peptide of FIG. 3 in any whole number increment up to the entire length of the protein, that includes an amino acid position having a value greater than 0.5 in the Percent Accessible Residues profile of FIG. 7 for that protein;

(30) a polynucleotide that encodes a peptide region of at least 5 amino acids of a peptide of FIG. 3 in any whole number increment up to the entire length of that protein, that includes an amino acid position having a value greater than 0.5 in the Average Flexibility profile of FIG. 8 for that protein;

(31) a polynucleotide that encodes a peptide region of at least 5 amino acids of a peptide of FIG. 3 in any whole number increment up to the entire length of the protein, that includes an amino acid position having a value greater than 0.5 in the Beta-turn profile of FIG. 9 for that protein;

(32) a polynucleotide that encodes a FIG. 2–related protein whose sequence is encoded by the cDNAs contained in the plasmid 74P3B3 that was deposited with American Type Culture Collection (ATCC) as Accession No. PTA-1892 on 19 May 2000;

(33) a polynucleotide that is fully complementary to a polynucleotide of any one of (1)-(32);

(34) a polynucleotide that selectively hybridizes under stringent conditions to a polynucleotide of (1) to (33);

(35) a peptide that is encoded by any of (1)-(32); and,

(36) a polynucleotide of any of (1)-(34) or peptide of (35) together with a pharmaceutical excipient and/or in a human unit dose form.

As used herein, a range is understood to specifically disclose all whole unit positions, i.e., integer positions, thereof.

Typical embodiments of the invention disclosed herein include the proteins of FIG. 2 polynucleotides that encode specific portions of the FIG. 2 mRNA sequences (and those which are complementary to such sequences) such as those that encode the proteins and/or fragments thereof, for example:

-   -   4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20,         21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36,         37, 38, 39, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100,         105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165,         170, 175, 180, 185, 190, 195, 200, 205, 210, 215, 220, 225, 230,         235, 240, 245, 250, 255, 260, 265, 270, 275, 280, 285, 290, 295,         300, 305, 310, 315, 320, 325, 330, 335, 340, 345, 350, 355, 360,         365, 370, 375, 380, 385, 390, 395, 400, 405, 410, 415, 420, 425,         430, 435, 440, 445, 450, 455, 460, 465, 470, 475, 480, 485, 490,         495, 500, 505, 510, 515, 520, 525, 530, 535, 540, 545, 550, 555,         560, 565, 570, 575, 580, 585, 590, 595, 600, 605, 610, 615, 620,         625, 630, 635, 640, 645, 650, 655, 660, 665, 670, 675, 680, 685,         690, 695, 700, 705, 710, 715, 720, 725, 730, 735, 740, 745, 750,         755, 760, 765, 770, 775, 780, 785, 790, 795, 800, 805, 810, 815,         820, 825, 830, 835, 840, 845, 850, 855, 860, 865, 870, 875, 880,         885, 890, 895, 900, 905, 910, 915, 920, 925, 930, 935, 940, 945,         950, 955, 960, 965, 970, 975, 980, 985, 990, 995, 1000, 1025,         1050, 1075, 1100, 1125, 1150, 1175, 1200, etc., or more         contiguous amino acids of a peptide of the invention.

For example, representative embodiments of the invention disclosed herein include: polynucleotides and their encoded peptides themselves encoding about amino acid 1 to about amino acid 10 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 10 to about amino acid 20 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 20 to about amino acid 30 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 30 to about amino acid 40 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 40 to about amino acid 50 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 50 to about amino acid 60 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 60 to about amino acid 70 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 70 to about amino acid 80 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 80 to about amino acid 90 of a FIG. 2 protein or variants thereof, polynucleotides encoding about amino acid 90 to about amino acid 100 of a FIG. 2 protein or variants thereof, or encoding regions from about amino acid 100 to amino acids later in the sequence, in increments of about 10 amino acids, ending at the carboxyl terminal amino acid of a protein of the invention, e.g. a protein set forth in FIG. 2 or FIG. 3. Accordingly polynucleotides encoding portions of the amino acid sequence (in increments of about 10 amino acids), of amino acids 100 through the carboxyl terminal amino acid of a FIG. 2 protein are embodiments of the invention. Wherein it is understood that each particular amino acid position discloses that position plus or minus five amino acid residues.

Polynucleotides encoding relatively long portions of a FIG. 2 protein are also within the scope of the invention. For example, polynucleotides encoding from about amino acid 1 (or 20 or 30 or 40 etc.) to about amino acid 20, (or 30, or 40 or 50 etc.) of a FIG. 2 protein or variants thereof can be generated by a variety of techniques well known in the art. These polynucleotide fragments can include any portion of gene of the invention as shown, e.g., in FIG. 2.

Additional illustrative embodiments of the invention disclosed herein include a protein of FIG. 2 polynucleotide fragments encoding one or more of the biological motifs contained within a FIG. 2 protein sequence or a variant sequence thereof, including one or more of the motif-bearing subsequences of a FIG. 2 protein or variant, e.g., set forth in Tables V-XVIII, Table XX, and/or Tables XXIII to XXVI. In another embodiment, typical polynucleotide fragments of the invention encode one or more of the regions of a FIG. 2 protein or variant thereof that exhibit homology to a known molecule. In another embodiment of the invention, typical polynucleotide fragments encode one or more of the FIG. 2 proteins or variants N-glycosylation sites, cAMP and cGMP-dependent protein kinase phosphorylation sites, casein kinase II phosphorylation sites or N-myristoylation site and amidation sites (see, e.g., Table XX).

II.A.) Uses Polynucleotides of the Invention

II.A.1.) Monitoring of Genetic Abnormalities

The polynucleotides of the preceding paragraphs have a number of different specific uses. The human genes set forth in FIG. 2 maps to the chromosomal locations set forth in Example 3. For example, because a FIG. 2 gene map to a particular chromosome, polynucleotides that encode different regions of the FIG. 2 proteins are used to characterize cytogenetic abnormalities of this chromosomal locale, such as abnormalities that are identified as being associated with various cancers. In certain genes, a variety of chromosomal abnormalities including rearrangements have been identified as frequent cytogenetic abnormalities in a number of different cancers (see e.g. Krajinovic et al., Mutat. Res. 382(3-4): 81-83 (1998); Johansson et al., Blood 86(10): 3905-3914 (1995) and Finger et al., P.N.A.S. 85(23): 9158-9162 (1988)). Thus, polynucleotides encoding specific regions of the FIG. 2 proteins provide new tools that can be used to delineate, with greater precision than previously possible, cytogenetic abnormalities in the chromosomal region that encodes the proteins set forth in FIG. 2 that may contribute to the malignant phenotype. In this context, these polynucleotides satisfy a need in the art for expanding the sensitivity of chromosomal screening in order to identify more subtle and less common chromosomal abnormalities (see e.g. Evans et al., Am. J. Obstet. Gynecol 171(4): 1055-1057 (1994)).

Furthermore, as the genes set forth in FIG. 2 are shown to be highly expressed in cancers, the FIG. 2 polynucleotides are used in methods assessing the status of the FIG. 2 gene products in normal versus cancerous tissues. Typically, polynucleotides that encode specific regions of the FIG. 2 proteins are used to assess the presence of perturbations (such as deletions, insertions, point mutations, or alterations resulting in a loss of an antigen etc.) in specific regions of the FIG. 2 genes, such as regions containing one or more motifs. Exemplary assays include both RT-PCR assays as well as single-strand conformation polymorphism (SSCP) analysis (see, e.g., Marrogi et al., J. Cutan. Pathol. 26(8): 369-378 (1999), both of which utilize polynucleotides encoding specific regions of a protein to examine these regions within the protein.

II.A.2.) Antisense Embodiments

Other specifically contemplated nucleic acid related embodiments of the invention disclosed herein are genomic DNA, cDNAs, ribozymes, and antisense molecules, as well as nucleic acid molecules based on an alternative backbone, or including alternative bases, whether derived from natural sources or synthesized, and include molecules capable of inhibiting the RNA or protein expression of a gene set forth in FIG. 2. For example, antisense molecules can be RNAs or other molecules, including peptide nucleic acids (PNAs) or non-nucleic acid molecules such as phosphorothioate derivatives, that specifically bind DNA or RNA in a base pair-dependent manner. A skilled artisan can readily obtain these classes of nucleic acid molecules using the FIG. 2 polynucleotides and polynucleotide sequences disclosed herein.

Antisense technology entails the administration of exogenous oligonucleotides that bind to a target polynucleotide located within the cells. The term “antisense” refers to the fact that such oligonucleotides are complementary to their intracellular targets, e.g., a gene of FIG. 2. See for example, Jack Cohen, Oligodeoxynucleotides, Antisense Inhibitors of Gene Expression, CRC Press, 1989; and Synthesis 1:1-5 (1988). The FIG. 2 antisense oligonucleotides of the present invention include derivatives such as S-oligonucleotides (phosphorothioate derivatives or S-oligos, see, Jack Cohen, supra), which exhibit enhanced cancer cell growth inhibitory action. S-oligos (nucleoside phosphorothioates) are isoelectronic analogs of an oligonucleotide (O-oligo) in which a nonbridging oxygen atom of the phosphate group is replaced by a sulfur atom. The S-oligos of the present invention can be prepared by treatment of the corresponding O-oligos with 3H-1,2-benzodithiol-3-one-1,1-dioxide, which is a sulfur transfer reagent. See, e.g., Iyer, R. P. et al., J. Org. Chem. 55:4693-4698 (1990); and Iyer, R. P. et al., J. Am. Chem. Soc. 112:1253-1254 (1990). Additionally, the FIG. 2 antisense oligonucleotides of the present invention include morpholino antisense oligonucleotides known in the art (see, e.g., Partridge et al., 1996, Antisense & Nucleic Acid Drug Development 6: 169-175).

The FIG. 2 antisense oligonucleotides of the present invention typically can be RNA or DNA that is complementary to and stably hybridizes with the first 100 5′ codons or last 100 3′ codons of a genomic sequence or the corresponding mRNA of the invention. Absolute complementarity is not required, although high degrees of complementarity are preferred. Use of an oligonucleotide complementary to this region allows for the selective hybridization to mRNA of the invention and not to mRNA specifying other regulatory subunits of protein kinase. In one embodiment, the FIG. 2 antisense oligonucleotides of the present invention are 15 to 30-mer fragments of the antisense DNA molecule that have a sequence that hybridizes to mRNA of the invention. Optionally, a FIG. 2 antisense oligonucleotide is a 30-mer oligonucleotide that is complementary to a region in the first 10 5′ codons or last 10 3′ codons of a gene set forth in FIG. 2. Alternatively, the antisense molecules are modified to employ ribozymes in the inhibition of expression of a gene set forth in FIG. 2, see, e.g., L. A. Couture & D. T. Stinchcomb; Trends Genet 12: 510-515 (1996).

II.A.3.) Primers and Primer Pairs

Further specific embodiments of the nucleotides of the invention include primers and primer pairs, which allow the specific amplification of polynucleotides of the invention or of any specific parts thereof, and probes that selectively or specifically hybridize to nucleic acid molecules of the invention or to any part thereof. Probes can be labeled with a detectable marker, such as, for example, a radioisotope, fluorescent compound, bioluminescent compound, a chemiluminescent compound, metal chelator or enzyme. Such probes and primers are used to detect the presence of a FIG. 2 polynucleotide in a sample and as a means for detecting a cell expressing a FIG. 2 protein.

Examples of such probes include polynucleotides comprising all or part of a human gene set forth in FIG. 2. Examples of primer pairs capable of specifically amplifying an mRNA of the invention are also disclosed herein. As will be understood by the skilled artisan, a great many different primers and probes can be prepared based on the sequences provided herein and used effectively to amplify and/or detect an mRNA of the invention.

The FIG. 2 polynucleotides of the invention are useful for a variety of purposes, including but not limited to their use as probes and primers for the amplification and/or detection of the FIG. 2 gene(s), mRNA(s), or fragments thereof; as reagents for the diagnosis and/or prognosis of prostate cancer and other cancers; as coding sequences capable of directing the expression of a FIG. 2 polypeptide; as tools for modulating or inhibiting the expression of a FIG. 2 gene(s) and/or translation of a FIG. 2 transcript(s); and as therapeutic agents.

The present invention includes the use of any probe as described herein to identify and isolate a gene set forth in FIG. 2 or FIG. 2–related nucleic acid sequence of the invention from a naturally occurring source, such as humans or other mammals, as well as the isolated nucleic acid sequence per se, which would comprise all or most of the sequences found in the probe used.

II.A.4.) Isolation of Nucleic Acid Molecules that Encode Proteins of the Invention

The cDNA sequences described herein, see, e.g., FIG. 2, enable the isolation of other polynucleotides encoding gene product(s) of the invention, as well as the isolation of polynucleotides encoding homologs of protein of FIG. 2, alternatively spliced isoforms, allelic variants, and mutant forms of agene product of a gene of the invention as well as polynucleotides that encode analogs of the FIG. 2–related proteins. Various molecular cloning methods that can be employed to isolate full length cDNAs encoding a FIG. 2 gene are well known (see, for example, Sambrook, J. et al., Molecular Cloning: A Laboratory Manual, 2d edition, Cold Spring Harbor Press, New York, 1989; Current Protocols in Molecular Biology. Ausubel et al., Eds., Wiley and Sons, 1995). For example, lambda phage cloning methodologies can be conveniently employed, using commercially available cloning systems (e.g., Lambda ZAP Express, Stratagene). Phage clones containing a FIG. 2 gene cDNA can be identified by probing with a labeled cDNA of FIG. 2 or a fragment thereof. For example, in one embodiment, a FIG. 2 cDNA or a portion thereof is synthesized and used as a probe to retrieve overlapping and full-length cDNAs corresponding to a gene set forth in FIG. 2. A gene set forth in FIG. 2 itself can be isolated by screening genomic DNA libraries, bacterial artificial chromosome libraries (BACs), yeast artificial chromosome libraries (YACs), and the like, with a respective gene in FIG. 2 DNA probe or primer.

II.A.5.) Recombinant Nucleic Acid Molecules and Host-Vector Systems

The invention also provides recombinant DNA or RNA molecules containing a polynucleotide, a fragment, analog or homologue thereof in accordance with the invention, including but not limited to phages, plasmids, phagemids, cosmids, YACs, BACs, as well as various viral and non-viral vectors well known in the art, and cells transformed or transfected with such recombinant DNA or RNA molecules. Methods for generating such molecules are well known (see, for example, Sambrook et al., 1989, supra).

The invention further provides a host-vector system comprising a recombinant DNA molecule containing polynucleotide (fragment, analog or homologue thereof) in accordance with the invention within a suitable prokaryotic or eukaryotic host cell. Examples of suitable eukaryotic host cells include a yeast cell, a plant cell, or an animal cell, such as a mammalian cell or an insect cell (e.g., a baculovirus-infectible cell such as an Sf9 or HighFive cell). Examples of suitable mammalian cells include various prostate cancer cell lines such as DU145 and TsuPr1, other transfectable or transducible prostate cancer cell lines, primary cells (PrEC), as well as a number of mammalian cells routinely used for the expression of recombinant proteins (e.g., COS, CHO, 293, 293T cells). More particularly, a polynucleotide comprising the coding sequence of a protein in FIG. 2 or a fragment, analog or homolog thereof can be used to generate FIG. 2 proteins or fragments thereof using any number of host-vector systems routinely used and widely known in the art.

A wide range of host-vector systems suitable for the expression of FIG. 2 proteins or fragments thereof are available, see for example, Sambrook et al., 1989, supra; Current Protocols in Molecular Biology, 1995, supra). Preferred vectors for mammalian expression include but are not limited to pcDNA 3.1 myc-His-tag (Invitrogen) and the retroviral vector pSRαtkneo (Muller et al., 1991, MCB 11: 1785). Using these expression vectors, proteins set forth in FIG. 2 can be expressed in several prostate cancer and non-prostate cell lines, including for example 293, 293T, rat-1, NIH 3T3 and TsuPr1. The host-vector systems of the invention are useful for the production of a FIG. 2 protein or fragment thereof. Such host-vector systems can be employed to study the functional properties of proteins set forth in FIG. 2 and of the proteins of FIG. 2 mutations or analogs.

Recombinant human proteins of the invention, e.g., set forth in FIG. 2, or an analog or homolog or fragment thereof can be produced by mammalian cells transfected with a construct containing a FIG. 2–related nucleotide. For example, 293T cells can be transfected with an expression plasmid encoding a protein of FIG. 2 or fragment, analog or homolog thereof, a FIG. 2–related protein is expressed in the 293T cells, and the recombinant protein of the invention is isolated using standard purification methods (e.g., affinity purification using antibodies of the invention, e.g., an antibody that specifically binds a protein of the invention such as one set forth in FIG. 2). In another embodiment, a FIG. 2 coding sequence is subcloned into the retroviral vector pSRαMSVtkneo and used to infect various mammalian cell lines, such as NIH 3T3, TsuPr1, 293 and rat-1 in order to establish cell lines that express a protein of the invention. Various other expression systems well known in the art can also be employed. Expression constructs encoding a leader peptide joined in frame to a FIG. 2 coding sequence can be used for the generation of a secreted form of recombinant FIG. 2 proteins.

As discussed herein, redundancy in the genetic code permits variation in the gene sequences set forth in FIG. 2. In particular, it is known in the art that specific host species often have specific codon preferences, and thus one can adapt the disclosed sequence as preferred for a desired host. For example, preferred analog codon sequences typically have rare codons (i.e., codons having a usage frequency of less than about 20% in known sequences of the desired host) replaced with higher frequency codons. Codon preferences for a specific species are calculated, for example, by utilizing codon usage tables.

Additional sequence modifications are known to enhance protein expression in a cellular host. These include elimination of sequences encoding spurious polyadenylation signals, exon/intron splice site signals, transposon-like repeats, and/or other such well-characterized sequences that are deleterious to gene expression. The GC content of the sequence is adjusted to levels average for a given cellular host, as calculated by reference to known genes expressed in the host cell. Where possible, the sequence is modified to avoid predicted hairpin secondary mRNA structures. Other useful modifications include the addition of a translational initiation consensus sequence at the start of the open reading frame, as described in Kozak, Mol. Cell Biol., 9:5073-5080 (1989). Skilled artisans understand that the general rule that eukaryotic ribosomes initiate translation exclusively at the 5′ proximal AUG codon is abrogated only under rare conditions (see, e.g., Kozak PNAS 92(7): 2662-2666, (1995) and Kozak NAR 15(20): 8125-8148 (1987)).

III.) Proteins of the Invention

Another aspect of the present invention provides FIG. 2–related proteins, i.e., proteins of the invention. Specific embodiments of FIG. 2–related proteins comprise a polypeptide having all or part of the amino acid sequence of a human protein set forth in FIG. 2. Alternatively, embodiments of FIG. 2 proteins comprise variant, homolog or analog polypeptides that have alterations in their amino acid sequence relative to a protein set forth in FIG. 2.

In general, naturally occurring allelic variants of a protein set forth in FIG. 2 shares a high degree of structural identity and homology (e.g., 90% or more homology). Typically, allelic variants of a FIG. 2 protein contain conservative amino acid substitutions within the protein sequences set forth in FIG. 2 described herein or contain a substitution of an amino acid from a corresponding position in a homologue of a protein set forth in FIG. 2. One class of FIG. 2 allelic variants are proteins that share a high degree of homology with at least a small region of a particular FIG. 2 amino acid sequence, but further contain a radical departure from the sequence, such as a non-conservative substitution, truncation, insertion or frame shift. In comparisons of protein sequences, the terms, similarity, identity, and homology each have a distinct meaning as appreciated in the field of genetics. Moreover, orthology and paralogy can be important concepts describing the relationship of members of a given protein family in one organism to the members of the same family in other organisms.

Amino acid abbreviations are provided in Table II. Conservative amino acid substitutions can frequently be made in a protein without altering either the conformation or the function of the protein. Proteins of the invention can comprise 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 conservative substitutions. Such changes include substituting any of isoleucine (I), valine (V), and leucine (L) for any other of these hydrophobic amino acids; aspartic acid (D) for glutamic acid (E) and vice versa; glutamine (Q) for asparagine (N) and vice versa; and serine (S) for threonine (T) and vice versa. Other substitutions can also be considered conservative, depending on the environment of the particular amino acid and its role in the three-dimensional structure of the protein. For example, glycine (G) and alanine (A) can frequently be interchangeable, as can alanine (A) and valine (V). Methionine (M), which is relatively hydrophobic, can frequently be interchanged with leucine and isoleucine, and sometimes with valine. Lysine (K) and arginine (R) are frequently interchangeable in locations in which the significant feature of the amino acid residue is its charge and the differing pK's of these two amino acid residues are not significant. Still other changes can be considered “conservative” in particular environments (see, e.g. Table III herein; pages 13-15 “Biochemistry” 2^(nd) ED. Lubert Stryer ed (Stanford University); Henikoff et al., PNAS 1992 Vol 89 10915-10919; Lei et al., J Biol Chem 1995 May 19; 270(20):11882-6).

Embodiments of the invention disclosed herein include a wide variety of art-accepted variants or analogs of FIG. 2 proteins such as polypeptides having amino acid insertions, deletions and substitutions. FIG. 2 variants can be made using methods known in the art such as site-directed mutagenesis, alanine scanning, and PCR mutagenesis. Site-directed mutagenesis (Carter et al., Nucl. Acids Res., 13:4331 (1986); Zoller et al., Nucl. Acids Res., 10:6487 (1987)), cassette mutagenesis (Wells et al., Gene, 34:315 (1985)), restriction selection mutagenesis (Wells et al., Philos. Trans. R. Soc. London SerA, 317:415 (1986)) or other known techniques can be performed on the cloned DNA to produce variant DNA in accordance with the invention.

Scanning amino acid analysis can also be employed to identify one or more amino acids along a contiguous sequence that is involved in a specific biological activity such as a protein-protein interaction. Among the preferred scanning amino acids are relatively small, neutral amino acids. Such amino acids include alanine, glycine, serine, and cysteine. Alanine is typically a preferred scanning amino acid among this group because it eliminates the side-chain beyond the beta-carbon and is less likely to alter the main-chain conformation of the variant. Alanine is also typically preferred because it is the most common amino acid. Further, it is frequently found in both buried and exposed positions (Creighton, The Proteins, (W.H. Freeman & Co., N.Y.); Chothia, J. Mol. Biol., 150:1 (1976)). If alanine substitution does not yield adequate amounts of variant, an isosteric amino acid can be used.

As defined herein, FIG. 2 variants, analogs or homologs, have the distinguishing attribute of having at least one epitope that is “cross reactive” with a protein of FIG. 2. As used in this sentence, “cross reactive” means that an antibody or T cell that specifically binds to a FIG. 2 variant also specifically binds to a FIG. 2 protein having an amino acid sequence set forth in FIG. 3. A polypeptide ceases to be a variant of a protein shown in FIG. 3, when it no longer contains any epitope capable of being recognized by an antibody or T cell that specifically binds to the starting of a FIG. 2 protein. Those skilled in the art understand that antibodies that recognize proteins bind to epitopes of varying size, and a grouping of the order of about four or five amino acids, contiguous or not, is regarded as a typical number of amino acids in a minimal epitope. See, e.g., Nair et al., J. Immunol 2000 165(12): 6949-6955; Hebbes et al., Mol Immunol (1989) 26(9):865-73; Schwartz et al., J Immunol (1985) 135(4):2598-608.

Other classes of FIG. 2–related protein variants share 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or more similarity, homology or identity with an amino acid sequence of FIG. 3, or a fragment thereof. Another specific class of FIG. 2 protein variants or analogs comprise one or more of the FIG. 2 biological motifs described herein (see, e.g., Table V or XVIII, Table XX, or Tables XXIII to XXVI) or presently known in the art. Thus, encompassed by the present invention are analogs of the proteins set forth in FIG. 2 fragments (nucleic or amino acid) that have altered functional (e.g. immunogenic) properties relative to the starting fragment. It is to be appreciated that motifs now or which become part of the art are to be applied to the nucleic or amino acid sequences of FIG. 2 or FIG. 3.

As discussed herein, embodiments of the claimed invention include polypeptides containing less than the full amino acid sequence of a protein shown in FIG. 2 or FIG. 3. For example, representative embodiments of the invention comprise peptides/proteins having any: 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, 170, 175, 180, 185, 190, 195, 200, 205, 210, 215, 220, 225, 230, 235, 240, 245, 250, 255, 260, 265, 270, 275, 280, 285, 290, 295, 300, 305, 310, 315, 320, 325, 330, 335, 340, 345, 350, 355, 360, 365, 370, 375, 380, 385, 390, 395, 400, 405, 410, 415, 420, 425, 430, 435, 440, 445, 450, 455, 460, 465, 470, 475, 480, 485, 490, 495, 500, 505, 510, 515, 520, 525, 530, 535, 540, 545, 550, 555, 560, 565, 570, 575, 580, 585, 590, 595, 600, 605, 610, 615, 620, 625, 630, 635, 640, 645, 650, 655, 660, 665, 670, 675, 680, 685, 690, 695, 700, 705, 710, 715, 720, 725, 730, 735, 740, 745, 750, 755, 760, 765, 770, 775, 780, 785, 790, 795, 800, 805, 810, 815, 820, 825, 830, 835, 840, 845, 850, 855, 860, 865, 870, 875, 880, 885, 890, 895, 900, 905, 910, 915, 920, 925, 930, 935, 940, 945, 950, 955, 960, 965, 970, 975, 980, 985, 990, 995, 1000, 1025, 1050, 1075, 1100, 1125, 1150, 1175, 1200, etc., or more contiguous amino acids of a protein shown in FIG. 2 or FIG. 3.

Moreover, representative embodiments of the invention disclosed herein include polypeptides consisting of about amino acid 1 to about amino acid 10 of a FIG. 2 protein shown, polypeptides consisting of about amino acid 10 to about amino acid 20 of a FIG. 2 protein, polypeptides consisting of about amino acid 20 to about amino acid 30 of a FIG. 2 protein, polypeptides consisting of about amino acid 30 to about amino acid 40 of a FIG. 2 protein, polypeptides consisting of about amino acid 40 to about amino acid 50 of a FIG. 2 protein, polypeptides consisting of about amino acid 50 to about amino acid 60 of a FIG. 2 protein, polypeptides consisting of about amino acid 60 to about amino acid 70 of a FIG. 2 protein, polypeptides consisting of about amino acid 70 to about amino acid 80 of a FIG. 2 protein, polypeptides consisting of about amino acid 80 to about amino acid 90 of a FIG. 2 protein, polypeptides consisting of about amino acid 90 to about amino acid 100 of a FIG. 2 protein, etc. throughout the entirety of a protein set forth in FIG. 2 amino acid sequence. Moreover, polypeptides consisting of about amino acid 1 (or 20 or 30 or 40 etc.) to about amino acid 20, (or 130, or 140 or 150 etc.) of a FIG. 2 protein are embodiments of the invention. It is to be appreciated that the starting and stopping positions in this paragraph refer to the specified position as well as that position plus or minus 5 residues.

FIG. 2–related proteins are generated using standard peptide synthesis technology or using chemical cleavage methods well known in the art. Alternatively, recombinant methods can be used to generate nucleic acid molecules that encode a FIG. 2–related protein. In one embodiment, nucleic acid molecules provide a means to generate defined fragments of a FIG. 2 protein (or variants, homologs or analogs thereof).

III.A.) Motif-Bearing Protein Embodiments

Additional illustrative embodiments of the invention disclosed herein include polypeptides of the invention that comprise the amino acid residues of one or more of the biological motifs contained within a protein of FIG. 2 polypeptide sequence set forth in FIG. 2 or FIG. 3. Various motifs are known in the art, and a protein can be evaluated for the presence of such motifs by a number of publicly available Internet sites. Accordingly, see, e.g., the motif bearing subsequences of all FIG. 2 proteins set forth and identified in Tables V to XVIII, Table XX, Table XXI, and Tables XXIII to XXVI. Additionally, Table XIX sets forth several frequently occurring motifs based on pfam searches. The columns of Table VIII list (1) motif name abbreviation, (2) percent identity found amongst the different member of the motif family, (3) motif name or description and (4) most common function; location information is included if the motif is relevant for location.

Polypeptides comprising one or more of the motifs set forth in Tables V to XVIII, Table XX, Table XXI, and Tables XXIII to XXVI are useful in elucidating the specific characteristics of a malignant phenotype in view of the observation that the motifs discussed above are associated with growth dysregulation and because the proteins of FIG. 2 are overexpressed in certain cancers (See, e.g., Table I). Casein kinase II, cAMP and camp-dependent protein kinase, and Protein Kinase C, for example, are enzymes known to be associated with the development of the malignant phenotype (see e.g. Chen et al., Lab Invest., 78(2): 165-174 (1998); Gaiddon et al., Endocrinology 136(10): 4331-4338 (1995); Hall et al., Nucleic Acids Research 24(6): 1119-1126 (1996); Peterziel et al., Oncogene 18(46): 6322-6329 (1999) and O'Brian, Oncol. Rep. 5(2): 305-309 (1998)). Moreover, both glycosylation and myristoylation are protein modifications also associated with cancer and cancer progression (see e.g. Dennis et al., Biochem. Biophys. Acta 1473(1):21-34 (1999); Raju et al., Exp. Cell Res. 235(1): 145-154 (1997)). Amidation is another protein modification also associated with cancer and cancer progression (see e.g. Treston et al., J. Natl. Cancer Inst. Monogr. (13): 169-175 (1992)).

In another embodiment, proteins of the invention comprise one or more of the immunoreactive epitopes identified in accordance with art-accepted methods, such as the peptides set forth in Tables V-XVIII and XXIII to XXVI. CTL epitopes can be determined using specific algorithms to identify peptides within a FIG. 2 protein that are capable of optimally binding to specified HLA alleles. Moreover, processes for identifying peptides that have sufficient binding affinity for HLA molecules and which are correlated with being immunogenic epitopes, are well known in the art, and are carried out without undue experimentation. In addition, processes for identifying peptides that are immunogenic epitopes, are well known in the art, and are carried out without undue experimentation either in vitro or in vivo.

Also known in the art are principles for creating analogs of such epitopes in order to modulate immunogenicity. For example, one begins with an epitope that bears a CTL or HTL motif (see, e.g., the HLA Class I and HLA Class II motifs/supermotifs of Table IV). The epitope is analoged by substituting out an amino acid at one of the specified positions, and replacing it with another amino acid specified for that position. For example, one can substitute out a deleterious residue in favor of any other residue, such as a preferred residue as defined in Table IV; substitute a less-preferred residue with a preferred residue as defined in Table IV; or substitute an originally-occurring preferred residue with another preferred residue as defined in Table IV. Substitutions can occur at primary anchor positions or at other positions in a peptide; see, e.g., Table IV.

A variety of references reflect the art regarding the identification and generation of epitopes in a protein of interest as well as analogs thereof. See, for example, WO 9733602 to Chesnut et al.; Sette, Immunogenetics 1999 50(3-4): 201-212; Sette et al., J. Immunol. 2001 166(2): 1389-1397; Sidney et al., Hum. Immunol. 1997 58(1): 12-20; Kondo et al., Immunogenetics 1997 45(4): 249-258; Sidney et al., J. Immunol. 1996 157(8): 3480-90; and Falk et al., Nature 351: 290-6 (1991); Hunt et al., Science 255:1261-3 (1992); Parker et al., J. Immunol. 149:3580-7 (1992); Parker et al., J. Immunol. 152:163-75 (1994)); Kast et al., 1994 152(8): 3904-12; Borras-Cuesta et al., Hum. Immunol. 2000 61(3): 266-278; Alexander et al., J. Immunol. 2000 164(3); 164(3): 1625-1633; Alexander et al., PMID: 7895164, UI: 95202582; O'Sullivan et al., J. Immunol. 1991 147(8): 2663-2669; Alexander et al., Immunity 1994 1(9): 751-761 and Alexander et al., Immunol. Res. 1998 18(2): 79-92.

Related embodiments of the inventions include polypeptides comprising combinations of the different motifs set forth in Table XIX; and/or, one or more of the predicted CTL epitopes of Tables V to XVIII, and/or, one or more of the predicted HTL epitopes of Tables XXIII to XXVI and/or, one or more of the T cell binding motifs known in the art. Preferred embodiments contain no insertions, deletions or substitutions either within the motifs or the intervening sequences of the polypeptides. In addition, embodiments which include a number of either N-terminal and/or C-terminal amino acid residues on either side of these motifs may be desirable (to, for example, include a greater portion of the polypeptide architecture in which the motif is located). Typically the number of N-terminal and/or C-terminal amino acid residues on either side of a motif is between about 1 to about 100 amino acid residues, preferably 5 to about 50 amino acid residues.

FIG. 2–related proteins are embodied in many forms, preferably in isolated form. A purified FIG. 2 protein molecule will be substantially free of other proteins or molecules that impair the binding of a protein of FIG. 2 to an antibody, T cell or other ligand. The nature and degree of isolation and purification will depend on the intended use. Embodiments of FIG. 2–related proteins include purified FIG. 2–related proteins and functional, soluble FIG. 2–related proteins. In one embodiment, a functional, soluble FIG. 2 protein or fragment thereof retains the ability to be bound by an antibody, T cell or other ligand.

The invention also provides FIG. 2 proteins comprising biologically active fragments of a FIG. 2 amino acid sequence. Such proteins exhibit properties of the starting FIG. 2 protein, such as the ability to elicit the generation of antibodies that specifically bind an epitope associated with the starting FIG. 2 protein; to be bound by such antibodies; to elicit the activation of HTL or CTL; and/or, to be recognized by HTL or CTL that also specifically bind to the starting protein.

FIG. 2–related polypeptides that contain particularly interesting structures can be predicted and/or identified using various analytical techniques well known in the art, including, for example, the methods of Chou-Fasman, Garnier-Robson, Kyte-Doolittle, Eisenberg, Karplus-Schultz or Jameson-Wolf analysis, or on the basis of immunogenicity. Fragments that contain such structures are particularly useful in generating subunit-specific antibodies that bind to a protein of FIG. 2, or T cells or in identifying cellular factors that bind to a protein set forth in FIG. 2. For example, hydrophilicity profiles can be generated, and immunogenic peptide fragments identified, using the method of Hopp, T. P. and Woods, K. R., 1981, Proc. Natl. Acad. Sci. U.S.A. 78:3824-3828. Hydropathicity profiles can be generated, and immunogenic peptide fragments identified, using the method of Kyte, J. and Doolittle, R. F., 1982, J. Mol. Biol. 157:105-132. Percent (%) Accessible Residues profiles can be generated, and immunogenic peptide fragments identified, using the method of Janin J., 1979, Nature 277:491-492. Average Flexibility profiles can be generated, and immunogenic peptide fragments identified, using the method of Bhaskaran R., Ponnuswamy P. K., 1988, Int. J. Pept. Protein Res. 32:242-255. Beta-turn profiles can be generated, and immunogenic peptide fragments identified, using the method of Deleage, G., Roux B., 1987, Protein Engineering 1:289-294.

CTL epitopes can be determined using specific algorithms to identify peptides within a FIG. 2 protein that are capable of optimally binding to specified HLA alleles. Illustrating this, peptide epitopes from the proteins set forth in FIG. 2 that are presented in the context of human MHC class I molecules HLA-A1, A2, A3, A11, A24, B7 and B35 were predicted (Tables V-XVIII). Specifically, the complete amino acid sequence of a FIG. 2 protein and relevant portions of other presented variants, i.e., for HLA Class I predictions 9 flanking residues on either side of a point mutation for 10-mers, and for HLA Class II predictions 14 flanking residues on either side of a point mutation for 15-mers, were entered into the HLA Peptide Motif Search algorithm; for HLA Class II SYFPEITHI was used for HTL epitopes of Tables XXIII to XXVI.

The HLA peptide motif search algorithm was developed by Dr. Ken Parker based on binding of specific peptide sequences in the groove of HLA Class I molecules, in particular HLA-A2 (see, e.g., Falk et al., Nature 351: 290-6 (1991); Hunt et al., Science 255:1261-3 (1992); Parker et al., J. Immunol. 149:3580-7 (1992); Parker et al., J. Immunol. 152:163-75 (1994)). This algorithm allows location and ranking of 8-mer, 9-mer, and 10-mer peptides from a complete protein sequence for predicted binding to HLA-A2 as well as numerous other HLA Class I molecules. Many HLA class I binding peptides are 8-, 9-, 10 or 11-mers. For example, for class I HLA-A2, the epitopes preferably contain a leucine (L) or methionine (M) at position 2 and a valine (V) or leucine (L) at the C-terminus (see, e.g., Parker et al., J. Immunol. 149:3580-7 (1992)). Selected results from a complete protein sequence set forth in FIG. 2 that predicted binding peptides are shown in Tables V-XVII. In Tables V-XVIII, the top 50 ranking candidates, 9-mers and 10-mers, for each family member are shown along with their location, the amino acid sequence of each specific peptide, and an estimated binding score. The binding score corresponds to the estimated half time of dissociation of complexes containing the peptide at 37° C. at pH 6.5. Peptides with the highest binding score are predicted to be the most tightly bound to HLA Class I on the cell surface for the greatest period of time and thus represent the best immunogenic targets for T-cell recognition.

Actual binding of peptides to an HLA allele can be evaluated by stabilization of HLA expression on the antigen-processing defective cell line T2 (see, e.g., Xue et al., Prostate 30:73-8 (1997) and Peshwa et al., Prostate 36:129-38 (1998)). Immunogenicity of specific peptides can be evaluated in vitro by stimulation of CD8+ cytotoxic T lymphocytes (CTL) in the presence of antigen presenting cells such as dendritic cells.

It is to be appreciated that every epitope predicted by the BIMAS site, Epimer™ and Epimatrix™ sites, or specified by the HLA class I or class II motifs available in the art or which become part of the art such as set forth in Table IV are to be “applied” to a FIG. 2 protein in accordance with the invention. As used in this context “applied” means that a FIG. 2 protein is evaluated, e.g., visually or by computer-based patterns finding methods, as appreciated by those of skill in the relevant art. Every subsequence of a FIG. 2 protein of 8, 9, 10, or 11 amino acid residues that bears an HLA Class I motif, or a subsequence of 9 or more amino acid residues that bear an HLA Class II motif are within the scope of the invention.

III.B.) Expression of FIG. 2–related Proteins

In an embodiment described in the examples that follow, the proteins set forth in FIG. 2 can be conveniently expressed in cells (such as 293T cells) transfected with a commercially available expression vector such as a CMV-driven expression vector encoding a protein of FIG. 2 with a C-terminal 6×His and MYC tag (pcDNA3.1/mycHIS, Invitrogen or Tag5, GenHunter Corporation, Nashville Tenn.). The Tag5 vector provides an IgGK secretion signal that can be used to facilitate the production of a secreted FIG. 2 protein in transfected cells. A secreted HIS-tagged FIG. 2 protein in the culture media can be purified, e.g., using a nickel column using standard techniques.

III.C.) Modifications of FIG. 2–related Proteins

Modifications of FIG. 2–related proteins such as covalent modifications are included within the scope of this invention. One type of covalent modification includes reacting targeted amino acid residues of a protein of FIG. 2 polypeptide with an organic derivatizing agent that is capable of reacting with selected side chains or the N- or C-terminal residues of a FIG. 2 protein. Another type of covalent modification to a protein of FIG. 2 polypeptide included within the scope of this invention comprises altering the native glycosylation pattern of a protein of the invention. Another type of covalent modification to a protein of FIG. 2 comprises linking a FIG. 2 polypeptide to one of a variety of nonproteinaceous polymers, e.g., polyethylene glycol (PEG), polypropylene glycol, or polyoxyalkylenes, in the manner set forth in U.S. Pat. No. 4,640,835; 4,496,689; 4,301,144; 4,670,417; 4,791,192 or 4,179,337.

FIG. 2–related proteins of the present invention can also be modified to form a chimeric molecule comprising a protein of FIG. 2 fused to another, heterologous polypeptide or amino acid sequence. Such a chimeric molecule can be synthesized chemically or recombinantly. A chimeric molecule can have a protein of the invention fused to another tumor-associated antigen or fragment thereof. Alternatively, a protein in accordance with the invention can comprise a fusion of fragments of a FIG. 2 sequence (amino or nucleic acid) such that a molecule is created that is not, through its length, directly homologous to the amino or nucleic acid sequences shown in FIG. 2 or FIG. 3. Such a chimeric molecule can comprise multiples of the same subsequence of a protein set forth in FIG. 2. A chimeric molecule can comprise a fusion of a FIG. 2–related protein with a polyhistidine epitope tag, which provides an epitope to which immobilized nickel can selectively bind, with cytokines or with growth factors. The epitope tag is generally placed at the amino- or carboxyl-terminus of a FIG. 2 protein. In an alternative embodiment, the chimeric molecule can comprise a fusion of a FIG. 2–related protein with an immunoglobulin or a particular region of an immunoglobulin. For a bivalent form of the chimeric molecule (also referred to as an “immunoadhesin”), such a fusion could be to the Fc region of an IgG molecule. The Ig fusions preferably include the substitution of a soluble (transmembrane domain deleted or inactivated) form of a FIG. 2 polypeptide in place of at least one variable region within an Ig molecule. In a preferred embodiment, the immunoglobulin fusion includes the hinge, CH2 and CH3, or the hinge, CH1, CH2 and CH3 regions of an IgG1 molecule. For the production of immunoglobulin fusions see, e.g., U.S. Pat. No. 5,428,130 issued Jun. 27, 1995.

III.D.) Uses of FIG. 2–related Proteins

The proteins of the invention have a number of different specific uses. As the proteins set forth in FIG. 2 are highly expressed in one or more cancers, FIG. 2–related proteins are used in methods that assess the status of FIG. 2 gene products in normal versus cancerous tissues, thereby elucidating the malignant phenotype. Typically, polypeptides from specific regions of a FIG. 2 protein are used to assess the presence of perturbations (such as deletions, insertions, point mutations etc.) in those regions (such as regions containing one or more motifs). Exemplary assays utilize antibodies or T cells targeting FIG. 2–related proteins comprising the amino acid residues of one or more of the biological motifs contained within a protein of FIG. 2 polypeptide sequence in order to evaluate the characteristics of this region in normal versus cancerous tissues or to elicit an immune response to the epitope. Alternatively, FIG. 2–related proteins that contain the amino acid residues of one or more of the biological motifs in a FIG. 2 protein are used to screen for factors that interact with that region of the respective protein set forth in FIG. 2.

FIG. 2 protein fragments/subsequences are particularly useful in generating and characterizing domain-specific antibodies (e.g., antibodies recognizing an extracellular or intracellular epitope of a FIG. 2 protein), for identifying agents or cellular factors that bind to a protein in FIG. 2 or a particular structural domain thereof, and in various therapeutic and diagnostic contexts, including but not limited to diagnostic assays, cancer vaccines and methods of preparing such vaccines.

Proteins encoded by a gene of the invention (e.g., a FIG. 2 gene, or analog, homolog or fragment thereof) have a variety of uses, including but not limited to generating antibodies and in methods for identifying ligands and other agents and cellular constituents that bind to a FIG. 2 gene product. Antibodies raised against a FIG. 2 protein or fragment thereof are useful in diagnostic and prognostic assays, and imaging methodologies in the management of human cancers characterized by expression of a FIG. 2 protein, such as those listed in Table I. Such antibodies can be expressed intracellularly and used in methods of treating patients with such cancers. FIG. 2–related nucleic acids or proteins are also used in generating HTL or CTL responses.

Various immunological assays useful for the detection of FIG. 2 proteins are used, including but not limited to various types of radioimmunoassays, enzyme-linked immunosorbent assays (ELISA), enzyme-linked immunofluorescent assays (ELIFA), immunocytochemical methods, and the like. Antibodies can be labeled and used as immunological imaging reagents capable of detecting cells that express a protein set forth in FIG. 2 (e.g., in radioscintigraphic imaging methods). FIG. 2 proteins are also particularly useful in generating cancer vaccines, as further described herein.

IV.) Antibodies of the Invention

Another aspect of the invention provides antibodies that bind to FIG. 2–related proteins. Preferred antibodies specifically bind to a FIG. 2–related protein and do not bind (or bind weakly) to peptides or proteins that are not FIG. 2–related proteins. For example, antibodies that bind to proteins in FIG. 2 can bind to FIG. 2–related proteins such as the homologs or analogs thereof.

Antibodies of the invention are particularly useful in cancer (see, e.g., the cancers referred to in Table I) diagnostic and prognostic assays, and imaging methodologies. Similarly, such antibodies are useful in the treatment, diagnosis, and/or prognosis of other cancers, to the extent the genes and respective encoded proteins set forth in FIG. 2 are also expressed or overexpressed in these other cancers. Moreover, intracellularly expressed antibodies (e.g., single chain antibodies) are therapeutically useful in treating cancers in which the expression of a gene and encoded protein of FIG. 2 is involved, such as advanced or metastatic prostate cancers.

The invention also provides various immunological assays useful for the detection and quantification a protein of FIG. 2 and mutants thereof. Such assays can comprise one or more FIG. 2 antibodies capable of recognizing and binding a FIG. 2–related protein, as appropriate. These assays are performed within various immunological assay formats well known in the art, including but not limited to various types of radioimmunoassays, enzyme-linked immunosorbent assays (ELISA), enzyme-linked immunofluorescent assays (ELIFA), and the like.

Immunological non-antibody assays of the invention also comprise T cell immunogenicity assays (inhibitory or stimulatory) as well as major histocompatibility complex (MHC) binding assays.

In addition, immunological imaging methods capable of detecting a cancer expressing a gene of the invention are also provided by the invention, including but not limited to radioscintigraphic imaging methods using labeled FIG. 2 antibodies. Such assays are clinically useful in the detection, monitoring, and prognosis of a gene of the invention-expressing cancer.

Antibodies of the invention are also used in methods for purifying a FIG. 2–related protein and for isolating proteins of the invention, e.g., FIG. 2 homologues and related molecules. For example, a method of purifying a FIG. 2–related protein comprises incubating a FIG. 2 antibody, which has been coupled to a solid matrix, with a lysate or other solution containing a FIG. 2–related protein under conditions that permit the antibody to bind to the FIG. 2–related protein; washing the solid matrix to eliminate impurities; and eluting the FIG. 2–related protein from the coupled antibody. Other uses of antibodies in accordance with the invention include generating anti-idiotypic antibodies that mimic a FIG. 2 protein.

Various methods for the preparation of antibodies are well known in the art. For example, antibodies can be prepared by immunizing a suitable mammalian host using a FIG. 2–related protein, peptide, or fragment, in isolated or immunoconjugated form (Antibodies: A Laboratory Manual, CSH Press, Eds., Harlow, and Lane (1988); Harlow, Antibodies, Cold Spring Harbor Press, NY (1989)). In addition, fusion proteins in accordance with the invention can also be used, such as a protein of FIG. 2 GST-fusion protein. In a particular embodiment, a GST fusion protein comprising all or most of the amino acid sequence of FIG. 2 or FIG. 3 is produced, then used as an immunogen to generate appropriate antibodies. In another embodiment, a FIG. 2–related protein is synthesized and used as an immunogen.

In addition, naked DNA immunization techniques known in the art are used (with or without a purified FIG. 2–related protein or agene of FIG. 2–expressing cells) to generate an immune response to the encoded immunogen (for review, see Donnelly et al., 1997, Ann. Rev. Immunol. 15: 617-648).

The amino acid sequence of a FIG. 2 protein can be analyzed to select specific regions of the protein for generating antibodies. For example, hydrophobicity and hydrophilicity analyses of FIG. 2 amino acid sequences are used to identify hydrophilic regions in the protein. Regions of a FIG. 2 protein that show immunogenic structure, as well as other regions and domains, can readily be identified using various other methods known in the art, such as Chou-Fasman, Garnier-Robson, Kyte-Doolittle, Eisenberg, Karplus-Schultz or Jameson-Wolf analysis. Hydrophilicity profiles can be generated using the method of Hopp, T. P. and Woods, K. R., 1981, Proc. Natl. Acad. Sci. U.S.A. 78:3824-3828. Hydropathicity profiles can be generated using the method of Kyte, J. and Doolittle, R. F., 1982, J. Mol. Biol. 157:105-132. Percent (%) Accessible Residues profiles can be generated using the method of Janin J., 1979, Nature 277:491-492. Average Flexibility profiles can be generated using the method of Bhaskaran R., Ponnuswamy P. K., 1988, Int. J. Pept. Protein Res. 32:242-255. Beta-turn profiles can be generated using the method of Deleage, G., Roux B., 1987, Protein Engineering 1:289-294. Thus, each region identified by any of these programs or methods is within the scope of the present invention. Methods for the generation of antibodies in accordance with the invention are further illustrated by way of the Examples provided herein. Methods for preparing a protein or polypeptide for use as an immunogen are well known in the art. Also well known in the art are methods for preparing immunogenic conjugates of a protein with a carrier, such as BSA, KLH or other carrier protein. In some circumstances, direct conjugation using, for example, carbodiimide reagents are used; in other instances linking reagents such as those supplied by Pierce Chemical Co., Rockford, Ill., are effective. Administration of protein immunogen is often conducted by injection over a suitable time period and with use of a suitable adjuvant, as is understood in the art. During the immunization schedule, titers of antibodies can be taken to determine adequacy of antibody formation.

Monoclonal antibodies of the invention can be produced by various means well known in the art. For example, immortalized cell lines that secrete a desired monoclonal antibody are prepared using the standard hybridoma technology of Kohler and Milstein or modifications that immortalize antibody-producing B cells, as is generally known. Immortalized cell lines that secrete the desired antibodies are screened by immunoassay in which the antigen is a FIG. 2–related protein. When the appropriate immortalized cell culture is identified, the cells can be expanded and antibodies produced either from in vitro cultures or from ascites fluid.

The antibodies or fragments of the invention can also be produced, by recombinant means. Regions that bind specifically to the desired regions of a FIG. 2 protein can also be produced in the context of chimeric or complementarity-determining region (CDR) grafted antibodies of multiple species origin. Humanized or human antibodies that specifically bind to a proteins of FIG. 2 can also be produced, and are preferred for use in therapeutic contexts. Methods for humanizing murine and other non-human antibodies, by substituting one or more of the non-human antibody CDRs for corresponding human antibody sequences, are well known (see for example, Jones et al., 1986, Nature 321: 522-525; Riechmann et al., 1988, Nature 332: 323-327; Verhoeyen et al., 1988, Science 239: 1534-1536). See also, Carter et al., 1993, Proc. Natl. Acad. Sci. USA 89: 4285 and Sims et al., 1993, J. Immunol. 151: 2296.

Methods for producing fully human monoclonal antibodies include phage display and transgenic methods (for review, see Vaughan et al., 1998, Nature Biotechnology 16: 535-539). Fully human monoclonal antibodies of the invention can be generated using cloning technologies employing large human Ig gene combinatorial libraries (i.e., phage display) (Griffiths and Hoogenboom, Building an in vitro immune system: human antibodies from phage display libraries. In: Protein Engineering of Antibody Molecules for Prophylactic and Therapeutic Applications in Man, Clark, M. (Ed.), Nottingham Academic, pp 45-64 (1993); Burton and Barbas, Human Antibodies from combinatorial libraries. Id., pp 65-82). Fully human monoclonal antibodies of the invention can also be produced using transgenic mice engineered to contain human immunoglobulin gene loci as described in PCT Patent Application WO98/24893, Kucherlapati and Jakobovits et al., published Dec. 3, 1997 (see also, Jakobovits, 1998, Exp. Opin. Invest. Drugs 7(4): 607-614; U.S. Pat. No. 6,162,963 issued 19 Dec. 2000; U.S. Pat. No. 6,150,584 issued 12 Nov. 2000; and, U.S. Pat. No. 6,114,598 issued 5 Sep. 2000). This method avoids the in vitro manipulation required with phage display technology and efficiently produces high affinity authentic human antibodies.

Reactivity of antibodies of the invention with a FIG. 2–related protein can be established by a number of well known means, including Western blot, immunoprecipitation, ELISA, and FACS analyses using, as appropriate, FIG. 2–related proteins, or protein of FIG. 2–expressing cells or extracts thereof. An FIG. 2 antibody of the invention, or fragment thereof, can be labeled with a detectable marker or conjugated to a second molecule. Suitable detectable markers include, but are not limited to, a radioisotope, a fluorescent compound, a bioluminescent compound, chemiluminescent compound, a metal chelator or an enzyme. Further, bi-specific antibodies specific for two or more epitopes are generated using methods generally known in the art. Homodimeric antibodies can also be generated by cross-linking techniques known in the art (e.g., Wolff et al., Cancer Res. 53: 2560-2565).

V.) Cellular Immune Responses of the Invention

The mechanism by which T cells recognize antigens has been delineated. Efficacious peptide epitope vaccine compositions of the invention induce a therapeutic or prophylactic immune responses in very broad segments of the world-wide population. For an understanding of the value and efficacy of compositions of the invention that induce cellular immune responses, a brief review of immunology-related technology is provided.

A complex of an HLA molecule and a peptidic antigen acts as the ligand recognized by HLA-restricted T cells (Buus, S. et al., Cell 47:1071, 1986; Babbitt, B. P. et al., Nature 317:359, 1985; Townsend, A. and Bodmer, H., Annu. Rev. Immunol. 7:601, 1989; Germain, R. N., Annu. Rev. Immunol. 11:403, 1993). Through the study of single amino acid substituted antigen analogs and the sequencing of endogenously bound, naturally processed peptides, critical residues that correspond to motifs required for specific binding to HLA antigen molecules have been identified and are set forth in Table IV (see also, e.g., Southwood, et al., J. Immunol. 160:3363, 1998; Rammensee, et al., Immunogenetics 41:178, 1995; Sette, A. and Sidney, J. Curr. Opin. Immunol. 10:478, 1998; Engelhard, V. H., Curr. Opin. Immunol. 6:13, 1994; Sette, A. and Grey, H. M., Curr. Opin. Immunol. 4:79, 1992; Sinigaglia, F. and Hammer, J. Curr. Biol. 6:52, 1994; Ruppert et al., Cell 74:929-937, 1993; Kondo et al., J. Immunol. 155:4307-4312, 1995; Sidney et al., J. Immunol. 157:3480-3490, 1996; Sidney et al., Human Immunol. 45:79-93, 1996; Sette, A. and Sidney, J. Immunogenetics 1999 November; 50(3-4):201-12, Review).

Furthermore, x-ray crystallographic analyses of HLA-peptide complexes have revealed pockets within the peptide binding cleft/groove of HLA molecules which accommodate, in an allele-specific mode, residues borne by peptide ligands; these residues in turn determine the HLA binding capacity of the peptides in which they are present. (See, e.g., Madden, D. R. Annu. Rev. Immunol. 13:587, 1995; Smith, et al., Immunity 4:203, 1996; Fremont et al., Immunity 8:305, 1998; Stern et al., Structure 2:245, 1994; Jones, E. Y. Curr. Opin. Immunol. 9:75, 1997; Brown, J. H. et al., Nature 364:33, 1993; Guo, H. C. et al., Proc. Natl. Acad. Sci. USA 90:8053, 1993; Guo, H. C. et al., Nature 360:364, 1992; Silver, M. L. et al., Nature 360:367, 1992; Matsumura, M. et al., Science 257:927, 1992; Madden et al., Cell 70:1035, 1992; Fremont, D. H. et al., Science 257:919, 1992; Saper, M. A., Bjorkman, P. J. and Wiley, D. C., J. Mol. Biol. 219:277, 1991.)

Accordingly, the definition of class I and class II allele-specific HLA binding motifs, or class I or class II supermotifs allows identification of regions within a protein that are correlated with binding to particular HLA antigen(s).

Thus, by a process of HLA motif identification, candidates for epitope-based vaccines have been identified; such candidates can be further evaluated by HLA-peptide binding assays to determine binding affinity and/or the time period of association of the epitope and its corresponding HLA molecule. Additional confirmatory work can be performed to select, amongst these vaccine candidates, epitopes with preferred characteristics in terms of population coverage, and/or immunogenicity.

Various strategies can be utilized to evaluate cellular immunogenicity, including:

-   -   1) Evaluation of primary T cell cultures from normal individuals         (see, e.g. Wentworth, P. A. et al., Mol. Immunol. 32:603, 1995;         Celis, E. et al., Proc. Natl. Acad. Sci. USA 91:2105, 1994;         Tsai, V. et al., J. Immunol. 158:1796, 1997; Kawashima, I. et         al., Human Immunol. 59:1, 1998). This procedure involves the         stimulation of peripheral blood lymphocytes (PBL) from normal         subjects with a test peptide in the presence of antigen         presenting cells in vitro over a period of several weeks. T         cells specific for the peptide become activated during this time         and are detected using, e.g., a lymphokine- or ⁵¹Cr-release         assay involving peptide sensitized target cells.     -   2) Immunization of HLA transgenic mice (see, e.g.,         Wentworth, P. A. et al., J. Immunol. 26:97, 1996;         Wentworth, P. A. et al., Int. Immunol 8:651, 1996; Alexander, J.         et al., J. Immunol. 159:4753, 1997). For example, in such         methods peptides in incomplete Freund's adjuvant are         administered subcutaneously to HLA transgenic mice. Several         weeks following immunization, splenocytes are removed and         cultured in vitro in the presence of test peptide for         approximately one week. Peptide-specific T cells are detected         using, e.g., a ⁵¹Cr-release assay involving peptide sensitized         target cells and target cells expressing endogenously generated         antigen.     -   3) Demonstration of recall T cell responses from immune         individuals who have been either effectively vaccinated and/or         from chronically ill patients (see, e.g. Rehermann, B. et         al., J. Exp. Med. 181:1047, 1995; Doolan, D. L. et al., Immunity         7:97, 1997; Bertoni, R. et al., J. Clin. Invest. 100:503, 1997;         Threlkeld, S. C. et al., J. Immunol. 159:1648, 1997;         Diepolder, H. M. et al., J. Virol. 71:6011, 1997). Accordingly,         recall responses are detected by culturing PBL from subjects         that have been exposed to the antigen due to disease and thus         have generated an immune response “naturally”, or from patients         who were vaccinated against the antigen. PBL from subjects are         cultured in vitro for 1-2 weeks in the presence of test peptide         plus antigen presenting cells (APC) to allow activation of         “memory” T cells, as compared to “naive” T cells. At the end of         the culture period, T cell activity is detected using assays         including ⁵¹Cr release involving peptide-sensitized targets, T         cell proliferation, or lymphokine release.

VI.) Transgenic Animals of the Invention

Nucleic acids that encode a FIG. 2–related protein can also be used to generate either transgenic animals or “knock out” animals that, in turn, are useful in the development and screening of therapeutically useful reagents. In accordance with established techniques, cDNA encoding a protein of FIG. 2 can be used to clone genomic DNA that encodes a protein of FIG. 2. The cloned genomic sequences can then be used to generate transgenic animals containing cells that express DNA that encode a FIG. 2 protein. Methods for generating transgenic animals, particularly animals such as mice or rats, have become conventional in the art and are described, for example, in U.S. Pat. No. 4,736,866 issued 12 Apr. 1988, and U.S. Pat. No. 4,870,009 issued 26 Sep. 1989. Typically, particular cells would be targeted for a nucleic acid sequence of FIG. 2 transgene incorporation with tissue-specific enhancers.

Transgenic animals that include a copy of a transgene encoding a FIG. 2 protein can be used to examine the effect of increased expression of DNA that encodes the FIG. 2 protein. Such animals can be used as tester animals for reagents thought to confer protection from, for example, pathological conditions associated with its overexpression. In accordance with this aspect of the invention, an animal is treated with a reagent and a reduced incidence of a pathological condition, compared to untreated animals that bear the transgene, would indicate a potential therapeutic intervention for the pathological condition.

Alternatively, non-human homologues of FIG. 2 proteins can be used to construct a FIG. 2 protein “knock out” animal that has a defective or altered gene encoding the FIG. 2 protein as a result of homologous recombination between the endogenous gene encoding the FIG. 2 protein and altered genomic DNA encoding the FIG. 2 protein, introduced into an embryonic cell of the animal. For example, cDNA that encodes a FIG. 2 protein can be used to clone genomic DNA encoding the FIG. 2 protein, in accordance with established techniques. A portion of the genomic DNA encoding a FIG. 2 protein can be deleted or replaced with another gene, such as a gene encoding a selectable marker that can be used to monitor integration. Typically, several kilobases of unaltered flanking DNA (both at the 5′ and 3′ ends) are included in the vector (see, e.g., Thomas and Capecchi, Cell, 51:503 (1987) for a description of homologous recombination vectors). The vector is introduced into an embryonic stem cell line (e.g., by electroporation) and cells in which the introduced DNA has homologously recombined with the endogenous DNA are selected (see, e.g., Li et al., Cell, 69:915 (1992)). The selected cells are then injected into a blastocyst of an animal (e.g., a mouse or rat) to form aggregation chimeras (see, e.g., Bradley, in Teratocarcinomas and Embryonic Stem Cells: A Practical Approach, E. J. Robertson, ed. (IRL, Oxford, 1987), pp. 113-152). A chimeric embryo can then be implanted into a suitable pseudopregnant female foster animal, and the embryo brought to term to create a “knock out” animal. Progeny harboring the homologously recombined DNA in their germ cells can be identified by standard techniques and used to breed animals in which all cells of the animal contain the homologously recombined DNA. Knock out animals can be characterized, for example, for their ability to defend against certain pathological conditions or for their development of pathological conditions due to absence of a protein of FIG. 2.

VII.) Methods for the Detection of a Gene or Protein of the Invention

Another aspect of the present invention relates to methods for detecting FIG. 2 polynucleotides and FIG. 2–related proteins, as well as methods for identifying a cell that expresses a gene set forth in FIG. 2. The expression profile of a gene or protein set forth in FIG. 2 makes it a diagnostic marker for metastasized disease. Accordingly, the status of FIG. 2 gene products provides information useful for predicting a variety of factors including susceptibility to advanced stage disease, rate of progression, and/or tumor aggressiveness. As discussed in detail herein, the status of FIG. 2 gene products in patient samples can be analyzed by a variety protocols that are well known in the art including immunohistochemical analysis, the variety of Northern blotting techniques including in situ hybridization, RT-PCR analysis (for example on laser capture micro-dissected samples), Western blot analysis and tissue array analysis.

More particularly, the invention provides assays for the detection of FIG. 2 polynucleotides in a biological sample, such as serum, bone, prostate, and other tissues, urine, semen, cell preparations, and the like. Detectable FIG. 2 polynucleotides include, for example, a FIG. 2 gene or fragment thereof, a FIG. 2 mRNA, alternative splice variants of FIG. 2 mRNAs, and recombinant DNA or RNA molecules that contain a FIG. 2 polynucleotide. A number of methods for amplifying and/or detecting the presence of FIG. 2 polynucleotides are well known in the art and can be employed in the practice of this aspect of the invention.

In one embodiment, a method for detecting an a FIG. 2 mRNA in a biological sample comprises producing cDNA from the sample by reverse transcription using at least one primer; amplifying the cDNA so produced using FIG. 2 polynucleotides as sense and antisense primers to amplify FIG. 2 cDNAs therein; and detecting the presence of the amplified FIG. 2 cDNA. Optionally, the sequence of the amplified FIG. 2 cDNA can be determined.

In another embodiment, a method of detecting a FIG. 2 gene in a biological sample comprises first isolating genomic DNA from the sample; amplifying the isolated genomic DNA using FIG. 2 polynucleotides as sense and antisense primers; and detecting the presence of the amplified FIG. 2 gene. Any number of appropriate sense and antisense probe combinations can be designed from a FIG. 2 nucleotide sequence and used for this purpose.

The invention also provides assays for detecting the presence of a FIG. 2 protein in a tissue or other biological sample such as serum, semen, bone, prostate, urine, cell preparations, and the like. Methods for detecting a FIG. 2–related protein are also well known and include, for example, immunoprecipitation, immunohistochemical analysis, Western blot analysis, molecular binding assays, ELISA, ELIFA and the like. For example, a method of detecting the presence of a FIG. 2–related protein in a biological sample comprises first contacting the sample with a FIG. 2 antibody, a FIG. 2–reactive fragment thereof, or a recombinant protein containing an antigen binding region of a FIG. 2 antibody; and then detecting the binding of a FIG. 2–related protein in the sample.

Methods for identifying a cell that expresses a gene of FIG. 2 are also within the scope of the invention. In one embodiment, an assay for identifying a cell that expresses a FIG. 2 gene comprises detecting the presence of a FIG. 2 mRNA in the cell. Methods for the detection of particular mRNAs in cells are well known and include, for example, hybridization assays using complementary DNA probes (such as in situ hybridization using labeled riboprobes to a gene of FIG. 2, Northern blot and related techniques) and various nucleic acid amplification assays (such as RT-PCR using complementary primers specific for genes of FIG. 2, and other amplification type detection methods, such as, for example, branched DNA, SISBA, TMA and the like). Alternatively, an assay for identifying a cell that expresses a FIG. 2 gene comprises detecting the presence of a FIG. 2–related protein in the cell or secreted by the cell. Various methods for the detection of proteins are well known in the art and are employed for the detection of FIG. 2–related proteins and cells that express FIG. 2–related proteins.

Expression analysis of FIG. 2 proteins is also useful as a tool for identifying and evaluating agents that modulate FIG. 2 gene expressions. For example, FIG. 2 gene expression is significantly upregulated in prostate cancer, and is expressed in cancers of the tissues listed in Table I. Identification of a molecule or biological agent that inhibits FIG. 2 gene expression or over-expression in cancer cells is of therapeutic value. For example, such an agent can be identified by using a screen that quantifies a FIG. 2 gene expression by RT-PCR, nucleic acid hybridization or antibody binding.

VIII.) Methods for Monitoring the Status of Genes and Proteins of the Invention

Oncogenesis is known to be a multistep process where cellular growth becomes progressively dysregulated and cells progress from a normal physiological state to precancerous and then cancerous states (see, e.g., Alers et al., Lab Invest. 77(5): 437-438 (1997) and Isaacs et al., Cancer Surv. 23: 19-32 (1995)). In this context, examining a biological sample for evidence of dysregulated cell growth (such as aberrant gene of FIG. 2 expression in cancers) allows for early detection of such aberrant physiology, before a pathologic state such as cancer has progressed to a stage that therapeutic options are more limited and or the prognosis is worse. In such examinations, the status of the genes and proteins in FIG. 2 in a biological sample of interest can be compared, for example, to the status of that gene and/or protein of FIG. 2 in a corresponding normal sample (e.g. a sample from that individual or alternatively another individual that is not affected by a pathology). An alteration in the status of a gene and/or protein of FIG. 2 in the biological sample (as compared to the normal sample) provides evidence of dysregulated cellular growth. In addition to using a biological sample that is not affected by a pathology as a normal sample, one can also use a predetermined normative value such as a predetermined normal level of mRNA expression (see, e.g., Grever et al., J. Comp. Neurol. 1996 Dec. 9; 376(2): 306-14 and U.S. Pat. No. 5,837,501) to compare the status of a gene or protein in a sample.

The term “status” in this context is used according to its art accepted meaning and refers to the condition or state of a gene and its products. Typically, skilled artisans use a number of parameters to evaluate the condition or state of a gene and its products. These include, but are not limited to the location of expressed gene products (including the location of gene of FIG. 2 expressing cells) as well as the level, and biological activity of expressed gene products (such as FIG. 2 mRNA, polynucleotides and polypeptides). Typically, an alteration in the status of a gene and/or protein of FIG. 2 comprises a change in the location of a protein FIG. 2 and/or cells that express a protein of FIG. 2 and/or an increase in FIG. 2 mRNA and/or protein expression.

The status in a sample of a gene or protein of FIG. 2 can be analyzed by a number of means well known in the art, including without limitation, immunohistochemical analysis, in situ hybridization, RT-PCR analysis on laser capture micro-dissected samples, Western blot analysis, and tissue array analysis. Typical protocols for evaluating the status of a FIG. 2 gene and gene product are found, for example in Ausubel et al. eds., 1995, Current Protocols In Molecular Biology, Units 2 (Northern Blotting), 4 (Southern Blotting), 15 (Immunoblotting) and 18 (PCR Analysis). Thus, the status of a gene or protein in FIG. 2 in a biological sample is evaluated by various methods utilized by skilled artisans including, but not limited to genomic Southern analysis (to examine, for example perturbations in a FIG. 2 gene), Northern analysis and/or PCR analysis of FIG. 2 mRNA (to examine, for example alterations in the polynucleotide sequences or expression levels of FIG. 2 mRNAs), and, Western and/or immunohistochemical analysis (to examine, for example alterations in polypeptide sequences, alterations in polypeptide localization within a sample, alterations in expression levels of FIG. 2 proteins and/or associations of FIG. 2 proteins with polypeptide binding partners). Detectable FIG. 2 polynucleotides include, for example, a FIG. 2 gene or fragment thereof, a FIG. 2 mRNA, alternative splice variants, FIG. 2 mRNAs, and recombinant DNA or RNA molecules containing a FIG. 2 polynucleotide.

The expression profile of each gene of FIG. 2 makes it a diagnostic marker for local and/or metastasized disease, and provides information on the growth or oncogenic potential of a biological sample. In particular, the status of agene or protein of FIG. 2 provides information useful for predicting susceptibility to particular disease stages, progression, and/or tumor aggressiveness. The invention provides methods and assays for determining the expression or mutational status of a gene of FIG. 2 and diagnosing cancers that express a gene of FIG. 2, such as cancers of the tissues listed in Table I. For example, because each gene of FIG. 2 mRNA is highly expressed in cancers relative to normal tissue, assays that evaluate the levels of FIG. 2 mRNA transcripts or proteins in a biological sample are used to diagnose a disease associated with dysregulation of a gene set forth in FIG. 2, and can provide prognostic information useful in defining appropriate therapeutic options.

The expression status of the genes and proteins set forth in FIG. 2 provides information including the presence, stage and location of dysplastic, precancerous and cancerous cells, predicting susceptibility to various stages of disease, and/or for gauging tumor aggressiveness. Moreover, the expression profile makes it useful as an imaging reagent for metastasized disease. Consequently, an aspect of the invention is directed to the various molecular prognostic and diagnostic methods for examining the status of these genes and proteins in biological samples such as those from individuals suffering from, or suspected of suffering from a pathology characterized by dysregulated cellular growth, such as cancer.

As described above, the status of the genes and proteins in FIG. 2 in a biological sample can be examined by a number of well-known procedures in the art. For example, the status of the genes and proteins in FIG. 2 in a biological sample taken from a specific location in the body can be examined by evaluating the sample for the presence or absence of a FIG. 2 protein expressing cells (e.g. those that express FIG. 2 mRNAs or proteins). This examination can provide evidence of dysregulated cellular growth, for example, when FIG. 2 protein-expressing cells are found in a biological sample that does not normally contain such cells (such as a lymph node), because such alterations in the status of the genes and proteins in FIG. 2 in a biological sample are often associated with dysregulated cellular growth. Specifically, one indicator of dysregulated cellular growth is the metastases of cancer cells from an organ of origin (such as the prostate) to a different area of the body (such as a lymph node). In this context, evidence of dysregulated cellular growth is important for example because occult lymph node metastases can be detected in a substantial proportion of patients with prostate cancer, and such metastases are associated with known predictors of disease progression (see, e.g., Murphy et al., Prostate 42(4): 315-317 (2000); Su et al., Semin. Surg. Oncol. 18(1): 17-28 (2000) and Freeman et al., J Urol 1995 August 154(2 Pt 1):474-8).

In one aspect, the invention provides methods for monitoring FIG. 2 gene products by determining the status of FIG. 2 gene products expressed by cells from an individual suspected of having a disease associated with dysregulated cell growth (such as hyperplasia or cancer) and then comparing the status so determined to the status of FIG. 2 gene products in a corresponding normal sample. The presence of aberrant FIG. 2 gene products in the test sample relative to the normal sample provides an indication of the presence of dysregulated cell growth within the cells of the individual.

In another aspect, the invention provides assays useful in determining the presence of cancer in an individual, comprising detecting a significant increase in FIG. 2 mRNA or protein expression in a test cell or tissue sample relative to expression levels in the corresponding normal cell or tissue. The presence of FIG. 2 mRNA can, for example, be evaluated in tissue samples including but not limited to those listed in Table I. The presence of significant FIG. 2 protein expression or over-expression in any of these tissues is useful to indicate the emergence, presence and/or severity of a cancer, where the corresponding normal tissues do not express FIG. 2 mRNA or express it at lower levels.

In a related embodiment, the genes and proteins in FIG. 2 status is determined at the protein level rather than at the nucleic acid level. For example, such a method comprises determining the level of a FIG. 2 protein expressed by cells in a test tissue sample and comparing the level so determined to the level of a FIG. 2 protein expressed in a corresponding normal sample. In one embodiment, the presence of a FIG. 2 protein is evaluated, for example, using immunohistochemical methods. Antibodies of the invention or binding partners capable of detecting a FIG. 2 protein expression are used in a variety of assay formats well known in the art for this purpose.

In a further embodiment, one can evaluate the status of FIG. 2 nucleotide and amino acid sequences in a biological sample in order to identify perturbations in the structure of these molecules. These perturbations can include insertions, deletions, substitutions and the like. Such evaluations are useful because perturbations in the nucleotide and amino acid sequences are observed in a large number of proteins associated with a growth dysregulated phenotype (see, e.g., Marrogi et al., 1999, J. Cutan. Pathol. 26(8):369-378). For example, a mutation in the sequence of a FIG. 2 gene can indicate the presence or promotion of a tumor. Such assays therefore have diagnostic and predictive value where a mutation in a FIG. 2 gene indicates a potential loss of function or increase in tumor growth.

A wide variety of assays for observing perturbations in nucleotide and amino acid sequences are well known in the art. For example, the size and structure of nucleic acid or amino acid sequences of FIG. 2, or the gene products of one of these genes are observed by the Northern, Southern, Western, PCR and DNA sequencing protocols as discussed herein. In addition, other methods for observing perturbations in nucleotide and amino acid sequences such as single strand conformation polymorphism analysis are well known in the art (see, e.g., U.S. Pat. No. 5,382,510 issued 7 Sep. 1999, and U.S. Pat. No. 5,952,170 issued 17 Jan. 1995).

Additionally, one can examine the methylation status of a FIG. 2 gene in a biological sample. Aberrant demethylation and/or hypermethylation of CpG islands in gene 5′ regulatory regions frequently occurs in immortalized and transformed cells, and can result in altered expression of various genes. For example, promoter hypermethylation of the pi-class glutathione S-transferase (a protein expressed in normal prostate but not expressed in >90% of prostate carcinomas) appears to permanently silence transcription of this gene and is the most frequently detected genomic alteration in prostate carcinomas (De Marzo et al., Am. J. Pathol. 155(6): 1985-1992 (1999)). In addition, this alteration is present in at least 70% of cases of high-grade prostatic intraepithelial neoplasia (PIN) (Brooks et al., Cancer Epidemiol. Biomarkers Prev., 1998, 7:531-536). In another example, expression of the LAGE-I tumor specific gene (which is not expressed in normal prostate but is expressed in 25-50% of prostate cancers) is induced by deoxy-azacytidine in lymphoblastoid cells, suggesting that tumoral expression is due to demethylation (Lethe et al., Int. J. Cancer 76(6): 903-908 (1998)). A variety of assays for examining methylation status of a gene are well known in the art. For example, one can utilize, in Southern hybridization approaches, methylation-sensitive restriction enzymes that cannot cleave sequences that contain methylated CpG sites to assess the methylation status of CpG islands. In addition, MSP (methylation specific PCR) can rapidly profile the methylation status of all the CpG sites present in a CpG island of a given gene. This procedure involves initial modification of DNA by sodium bisulfite (which will convert all unmethylated cytosines to uracil) followed by amplification using primers specific for methylated versus unmethylated DNA. Protocols involving methylation interference can also be found for example in Current Protocols In Molecular Biology, Unit 12, Frederick M. Ausubel et al eds., 1995.

Gene amplification is an additional method for assessing the status of a FIG. 2 gene. Gene amplification is measured in a sample directly, for example, by conventional Southern blotting or Northern blotting to quantitate the transcription of mRNA (Thomas, 1980, Proc. Natl. Acad. Sci. USA, 77:5201-5205), dot blotting (DNA analysis), or in situ hybridization, using an appropriately labeled probe, based on the sequences provided herein. Alternatively, antibodies are employed that recognize specific duplexes, including DNA duplexes, RNA duplexes, and DNA-RNA hybrid duplexes or DNA-protein duplexes. The antibodies in turn are labeled and the assay carried out where the duplex is bound to a surface, so that upon the formation of duplex on the surface, the presence of antibody bound to the duplex can be detected.

Biopsied tissue or peripheral blood can be conveniently assayed for the presence of cancer cells using for example, Northern, dot blot or RT-PCR analysis to detect expression of a gene of FIG. 2. The presence of RT-PCR amplifiable FIG. 2 mRNA provides an indication of the presence of cancer. RT-PCR assays are well known in the art. RT-PCR detection assays for tumor cells in peripheral blood are currently being evaluated for use in the diagnosis and management of a number of human solid tumors. In the prostate cancer field, these include RT-PCR assays for the detection of cells expressing PSA and PSM (Verkaik et al., 1997, Urol. Res. 25:373-384; Ghossein et al., 1995, J. Clin. Oncol. 13:1195-2000; Heston et al., 1995, Clin. Chem. 41:1687-1688).

A further aspect of the invention is an assessment of the susceptibility that an individual has for developing cancer. In one embodiment, a method for predicting susceptibility to cancer comprises detecting FIG. 2 mRNA or a protein of the invention in a tissue sample, its presence indicating susceptibility to cancer, wherein the degree of FIG. 2 mRNA expression correlates to the degree of susceptibility. In a specific embodiment, the presence of a protein of the invention in, e.g., prostate tissue is examined, with the presence of a protein of FIG. 2 in the sample providing an indication of prostate cancer susceptibility (or the emergence or existence of a prostate tumor). Similarly, one can evaluate the integrity a gene in FIG. 2 nucleotide and amino acid sequences in a biological sample, in order to identify perturbations in the structure of these molecules such as insertions, deletions, substitutions and the like. The presence of one or more perturbations in genes or gene products of the invention in the sample is an indication of cancer susceptibility (or the emergence or existence of a tumor).

The invention also comprises methods for gauging tumor aggressiveness. In one embodiment, a method for gauging aggressiveness of a tumor comprises determining the level of FIG. 2 mRNA or a FIG. 2 protein expressed by tumor cells, comparing the level so determined to the level of FIG. 2 mRNA or a FIG. 2 protein expressed in a corresponding normal tissue taken from the same individual or a normal tissue reference sample, wherein the degree of FIG. 2 mRNA or a FIG. 2 protein expression in the tumor sample relative to the normal sample indicates the degree of aggressiveness. In a specific embodiment, aggressiveness of a tumor is evaluated by determining the extent to which a gene of FIG. 2 is expressed in the tumor cells, with higher expression levels indicating more aggressive tumors. Another embodiment is the evaluation of the integrity of FIG. 2 nucleotide and/or amino acid sequences in a biological sample, in order to identify perturbations in the structure of these molecules such as insertions, deletions, substitutions and the like. The presence of one or more perturbations indicates more aggressive tumors.

Another embodiment of the invention is directed to methods for observing the progression of a malignancy in an individual over time. In one embodiment, methods for observing the progression of a malignancy in an individual over time comprise determining the level of FIG. 2 mRNA or a FIG. 2 protein expressed by cells in a sample of the tumor, comparing the level so determined to the level of FIG. 2 mRNA or a FIG. 2 protein expressed in an equivalent tissue sample taken from the same individual at a different time, wherein the degree of FIG. 2 mRNA or a FIG. 2 protein expression in the tumor sample over time provides information on the progression of the cancer. In a specific embodiment, the progression of a cancer is evaluated by determining FIG. 2 gene or protein expression in the tumor cells over time, where increased expression over time indicates a progression of the cancer. Also, one can evaluate the integrity of FIG. 2 nucleotide and amino acid sequences in a biological sample in order to identify perturbations in the structure of these molecules such as insertions, deletions, substitutions and the like, where the presence of one or more perturbations indicates a progression of the cancer.

The above diagnostic approaches can be combined with any one of a wide variety of prognostic and diagnostic protocols known in the art. For example, another embodiment of the invention is directed to methods for observing a coincidence between the expression of a FIG. 2 gene and/or FIG. 2 gene products (or perturbations in a FIG. 2 gene and/or FIG. 2 gene products) and a factor that is associated with malignancy, as a means for diagnosing and prognosticating the status of a tissue sample. A wide variety of factors associated with malignancy can be utilized, such as the expression of genes associated with malignancy (e.g. PSA, PSCA and PSM expression for prostate cancer, etc.) as well as gross cytological observations (see, e.g., Bocking et al., 1984, Anal. Quant. Cytol. 6(2):74-88; Epstein, 1995, Hum. Pathol. 26(2):223-9; Thorson et al., 1998, Mod. Pathol. 11(6):543-51; Baisden et al., 1999, Am. J. Surg. Pathol. 23(8):918-24). Methods for observing a coincidence between the expression of a FIG. 2 gene and/or FIG. 2 gene products (or perturbations in a FIG. 2 gene and/or FIG. 2 gene products) and another factor that is associated with malignancy are useful, for example, because the presence of a set of specific factors that coincide with disease provides information crucial for diagnosing and prognosticating the status of a tissue sample.

In one embodiment, methods for observing a coincidence between the expression of a FIG. 2 gene and FIG. 2 gene products (or perturbations in a FIG. 2 gene and/or FIG. 2 gene products) and another factor associated with malignancy entails detecting the overexpression of FIG. 2 mRNA and/or protein in a tissue sample; detecting the overexpression of PSA mRNA or protein in a tissue sample (or PSCA or PSM expression, etc.), and observing a coincidence of FIG. 2 mRNA and/or protein and PSA mRNA or protein overexpression (or PSCA or PSM expression). In a specific embodiment, the expression of a gene of FIG. 2 and PSA mRNA in prostate tissue is examined, where the coincidence of a FIG. 2 gene and PSA mRNA overexpression in the sample indicates the existence of prostate cancer, prostate cancer susceptibility or the emergence or status of a prostate tumor.

Methods for detecting and quantifying the expression of FIG. 2 mRNA or protein are described herein, and standard nucleic acid and protein detection and quantification technologies are well known in the art. Standard methods for the detection and quantification of FIG. 2 mRNA include in situ hybridization using labeled FIG. 2 gene riboprobes, Northern blot and related techniques using FIG. 2 polynucleotide probes, RT-PCR analysis using primers specific for FIG. 2 genes, and other amplification type detection methods, such as, for example, branched DNA, SISBA, TMA and the like. In a specific embodiment, semi-quantitative RT-PCR is used to detect and quantify FIG. 2 mRNA expression. Any number of primers capable of amplifying a FIG. 2 gene can be used for this purpose, including but not limited to the various primer sets specifically described herein. In a specific embodiment, polyclonal or monoclonal antibodies specifically reactive with a wild-type FIG. 2 protein can be used in an immunohistochemical assay of biopsied tissue.

IX.) Identification of Molecules that Interact with Proteins of FIG. 2

The FIG. 2 protein and nucleic acid sequences disclosed herein allow a skilled artisan to identify proteins, small molecules and other agents that interact with the genes or proteins in FIG. 2, as well as pathways activated by genes or proteins in FIG. 2 via any one of a variety of art accepted protocols. For example, one can utilize one of the so-called interaction trap systems (also referred to as the “two-hybrid assay”). In such systems, molecules interact and reconstitute a transcription factor which directs expression of a reporter gene, whereupon the expression of the reporter gene is assayed. Other systems identify protein-protein interactions in vivo through reconstitution of a eukaryotic transcriptional activator, see, e.g., U.S. Pat. No. 5,955,280 issued 21 Sep. 1999, U.S. Pat. No. 5,925,523 issued 20 Jul. 1999, U.S. Pat. No. 5,846,722 issued 8 Dec. 1998 and U.S. Pat. No. 6,004,746 issued 21 Dec. 1999. Algorithms are also available in the art for genome-based predictions of protein function (see, e.g., Marcotte, et al., Nature 402: 4 Nov. 1999, 83-86).

Alternatively one can screen peptide libraries to identify molecules that interact with a protein sequence of the invention, e.g., a protein of FIG. 2. In such methods, peptides that bind to FIG. 2 proteins are identified by screening libraries that encode a random or controlled collection of amino acids. Peptides encoded by the libraries are expressed as fusion proteins of bacteriophage coat proteins, the bacteriophage particles are then screened against a FIG. 2 protein(s).

Accordingly, peptides having a wide variety of uses, such as therapeutic, prognostic or diagnostic reagents, are thus identified without any prior information on the structure of the expected ligand or receptor molecule. Typical peptide libraries and screening methods that can be used to identify molecules that interact with FIG. 2 protein sequences are disclosed for example in U.S. Pat. No. 5,723,286 issued 3 Mar. 1998 and U.S. Pat. No. 5,733,731 issued 31 Mar. 1998.

Alternatively, cell lines that express a protein of FIG. 2 are used to identify protein-protein interactions mediated by the respective proteins of FIG. 2. Such interactions can be examined using immunoprecipitation techniques (see, e.g., Hamilton B. J., et al. Biochem. Biophys. Res. Commun. 1999, 261:646-51). FIG. 2 proteins can be immunoprecipitated from the respective proteins of FIG. 2–expressing cell line using antibodies of the invention that specifically bind that protein. Alternatively, antibodies against His-tag can be used in a cell line engineered to express fusions of a protein of FIG. 2 and a His-tag (vectors mentioned above). The immunoprecipitated complex can be examined for protein association by procedures such as Western blotting, ³⁵S-methionine labeling of proteins, protein microsequencing, silver staining and two-dimensional gel electrophoresis.

Small molecules and ligands that interact with the genes and proteins in FIG. 2 can be identified through related embodiments of such screening assays. For example, small molecules can be identified that interfere with protein function, including molecules that interfere with protein of the invention's ability to mediate phosphorylation and de-phosphorylation, interaction with DNA or RNA molecules as an indication of regulation of cell cycles, second messenger signaling or tumorigenesis. Similarly, small molecules that modulate a proteins of FIG. 2–related ion channel, protein pump, or cell communication functions are identified and used to treat patients that have a cancer that expresses a FIG. 2 gene (see, e.g., Hille, B., Ionic Channels of Excitable Membranes 2^(nd) Ed., Sinauer Assoc., Sunderland, Mass., 1992). Moreover, ligands that regulate the function of a protein of the invention can be identified based on their ability to bind proteins of the invention and activate a reporter construct. Typical methods are discussed for example in U.S. Pat. No. 5,928,868 issued 27 Jul. 1999, and include methods for forming hybrid ligands in which at least one ligand is a small molecule. In an illustrative embodiment, cells engineered to express a fusion protein of a FIG. 2 protein and a DNA-binding protein are used to co-express a fusion protein of a hybrid ligand/small molecule and a cDNA library transcriptional activator protein. The cells further contain a reporter gene, the expression of which is conditioned on the proximity of the first and second fusion proteins to each other, an event that occurs only if the hybrid ligand binds to target sites on both hybrid proteins. Those cells that express the reporter gene are selected and the unknown small molecule or the unknown ligand is identified. This method provides a means of identifying modulators which activate or inhibit a protein of the invention.

An embodiment of the invention comprises a method of screening for a molecule that interacts with a protein of the invention, e.g., an amino acid sequence shown in FIG. 2 or FIG. 3, comprising the steps of contacting a population of molecules with a FIG. 2 amino acid sequence, allowing the population of molecules and the FIG. 2 amino acid sequence to interact under conditions that facilitate an interaction, determining the presence of a molecule that interacts with the FIG. 2 amino acid sequence, and then separating molecules that do not interact with the FIG. 2 amino acid sequence from molecules that do. In a specific embodiment, the method further comprises purifying, characterizing and identifying a molecule that interacts with the FIG. 2 amino acid sequence. The identified molecule can be used to modulate a function performed by a protein of the invention. In a preferred embodiment, the protein in FIG. 2 amino acid sequence is contacted with a library of peptides.

X.) Therapeutic Methods and Compositions

The identification of a FIG. 2 as a protein that is normally expressed in a restricted set of tissues, but which is also expressed in certain cancers, opens a number of therapeutic approaches to the treatment of such cancers. As contemplated herein, the genes and proteins in FIG. 2 function as a transcription factor involved in activating tumor-promoting genes or repressing genes that block tumorigenesis.

Accordingly, therapeutic approaches that inhibit the activity of a FIG. 2 protein are useful for patients suffering from a cancer that expresses a gene of FIG. 2. These therapeutic approaches generally fall into two classes. One class comprises various methods for inhibiting the binding or association of a FIG. 2 protein with its binding partner or with other proteins. Another class comprises a variety of methods for inhibiting the transcription of a FIG. 2 gene or translation of FIG. 2 mRNA.

X.A.) Anti-Cancer Vaccines

The invention provides cancer vaccines comprising a FIG. 2–related protein or a FIG. 2–related nucleic acid. In view of the expression of a FIG. 2 protein, cancer vaccines prevent and/or treat genes of FIG. 2–expressing cancers with minimal or no effects on non-target tissues. The use of a tumor antigen in a vaccine that generates humoral and/or cell-mediated immune responses as anti-cancer therapy is well known in the art and has been employed in prostate cancer using human PSMA and rodent PAP immunogens (Hodge et al., 1995, Int. J. Cancer 63:231-237; Fong et al., 1997, J. Immunol. 159:3113-3117).

Such methods can be readily practiced by employing a FIG. 2–related protein, or a nucleic acid sequence that encodes a FIG. 2–related protein and recombinant vectors capable of expressing and presenting immunogen of the invention (which typically comprises a number of antibody or T cell epitopes). Skilled artisans understand that a wide variety of vaccine systems for delivery of immunoreactive epitopes are known in the art (see, e.g., Heryln et al., Ann Med 1999 February 31(1):66-78; Maruyama et al., Cancer Immunol Immunother 2000 June 49(3):123-32) Briefly, such methods of generating an immune response (e.g. humoral and/or cell-mediated) in a mammal, comprise the steps of: exposing the mammal's immune system to an immunoreactive epitope (e.g. an epitope present in a protein of the invention, e.g., shown in FIG. 3 or analog or homolog thereof) so that the mammal generates an immune response that is specific for that epitope (e.g. generates antibodies that specifically recognize that epitope). In a preferred method, an immunogen contains a biological motif, see e.g., Tables V-XVIII, Tables XXIII to XXVI; or a peptide of a size range from a protein in FIG. 2 indicated in FIG. 5, FIG. 6, FIG. 7, FIG. 8, and/or FIG. 9.

The entire FIG. 2 protein, immunogenic regions or epitopes thereof can be combined and delivered by various means. Such vaccine compositions can include, for example, lipopeptides (e.g., Vitiello, A. et al., J. Clin. Invest. 95:341, 1995), peptide compositions encapsulated in poly(DL-lactide-co-glycolide) (“PLG”) microspheres (see, e.g., Eldridge, et al., Molec. Immunol. 28:287-294, 1991: Alonso et al., Vaccine 12:299-306, 1994; Jones et al., Vaccine 13:675-681, 1995), peptide compositions contained in immune stimulating complexes (ISCOMS) (see, e.g., Takahashi et al., Nature 344:873-875, 1990; Hu et al., Clin Exp Immunol. 113:235-243, 1998), multiple antigen peptide systems (MAPs) (see e.g., Tam, J. P., Proc. Natl. Acad. Sci. U.S.A. 85:5409-5413, 1988; Tam, J. P., J. Immunol. Methods 196:17-32, 1996), peptides formulated as multivalent peptides; peptides for use in ballistic delivery systems, typically crystallized peptides, viral delivery vectors (Perkus, M. E. et al., In: Concepts in vaccine development, Kaufmann, S. H. E., ed., p. 379, 1996; Chakrabarti, S. et al., Nature 320:535, 1986; Hu, S. L. et al., Nature 320:537, 1986; Kieny, M.-P. et al., AIDS Bio/Technology 4:790, 1986; Top, F. H. et al., J. Infect. Dis. 124:148, 1971; Chanda, P. K. et al., Virology 175:535, 1990), particles of viral or synthetic origin (e.g., Kofler, N. et al., J. Immunol. Methods. 192:25, 1996; Eldridge, J. H. et al., Sem. Hematol. 30:16, 1993; Falo, L. D., Jr. et al., Nature Med 7:649, 1995), adjuvants (Warren, H. S., Vogel, F. R., and Chedid, L. A. Annu. Rev. Immunol. 4:369, 1986; Gupta, R. K. et al., Vaccine 11:293, 1993), liposomes (Reddy, R. et al., J. Immunol. 148:1585, 1992; Rock, K. L., Immunol Today 17:131, 1996), or, naked or particle absorbed cDNA (Ulmer, J. B. et al., Science 259:1745, 1993; Robinson, H. L., Hunt, L. A., and Webster, R. G., Vaccine 11:957, 1993; Shiver, J. W. et al., In: Concepts in vaccine development, Kaufmann, S. H. E., ed., p. 423, 1996; Cease, K. B., and Berzofsky, J. A., Annu. Rev. Immunol. 12:923, 1994 and Eldridge, J. H. et al., Sem. Hematol. 30:16, 1993). Toxin-targeted delivery technologies, also known as receptor mediated targeting, such as those of Avant Immunotherapeutics, Inc. (Needham, Mass.) may also be used.

In patients with a protein of FIG. 2–associated cancer, the vaccine compositions of the invention can also be used in conjunction with other treatments used for cancer, e.g., surgery, chemotherapy, drug therapies, radiation therapies, etc. including use in combination with immune adjuvants such as IL-2, IL-12, GM-CSF, and the like.

Cellular Vaccines:

CTL epitopes can be determined using specific algorithms to identify peptides within a FIG. 2 protein that bind corresponding HLA alleles. In a preferred embodiment, an of the invention contains one or more amino acid sequences identified using techniques well known in the art, such as the sequences shown in Tables V-XVIII or a peptide of 8, 9, 10 or 11 amino acids specified by an HLA Class I motif/supermotif (e.g., Table IV (A), Table IV (D), or Table IV (E)) and/or a peptide of at least 9 amino acids that comprises an HLA Class II motif/supermotif (e.g., Table IV (B) or Table IV (C)). As is appreciated in the art, the HLA Class I binding groove is essentially closed ended so that peptides of only a particular size range can fit into the groove and be bound, generally HLA Class I epitopes are 8, 9, 10, or 11 amino acids long. In contrast, the HLA Class II binding groove is essentially open ended; therefore a peptide of about 9 or more amino acids can be bound by an HLA Class II molecule, as a convention 15-mer peptides that bind to HLA class II alleles are generally presented (see, e.g., Tables XXIII to XXVI). Due to the binding groove differences between HLA Class I and II, HLA Class I motifs are length specific, i.e., position two of a Class I motif is the second amino acid in an amino to carboxyl direction of the peptide. The amino acid positions in a Class II motif are relative only to each other, not the overall peptide, i.e., additional amino acids can be attached to the amino and/or carboxyl termini of a motif-bearing sequence. HLA Class II epitopes are often 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, or 25 amino acids long, or longer than 25 amino acids.

Antibody-based Vaccines

A wide variety of methods for generating an immune response in a mammal are known in the art (for example as the first step in the generation of hybridomas). Methods of generating an immune response in a mammal comprise exposing the mammal's immune system to an immunogenic epitope on a protein (e.g. a FIG. 2 protein) so that an immune response is generated. A typical embodiment consists of a method for generating an immune response to a protein in FIG. 2 in a host, by contacting the host with a sufficient amount of at least one protein in FIG. 2 B cell or cytotoxic T-cell epitope or analog thereof; and at least one periodic interval thereafter re-contacting the host with the B cell or cytotoxic T-cell epitope or analog thereof. A specific embodiment consists of a method of generating an immune response against a FIG. 2–related protein or a man-made multiepitopic peptide comprising: administering an immunogen of the invention (e.g. a FIG. 2 protein or a peptide fragment thereof, an FIG. 2 fusion protein or analog etc.) in a vaccine preparation to a human or another mammal. Typically, such vaccine preparations further contain a suitable adjuvant (see, e.g., U.S. Pat. No. 6,146,635) or a universal helper epitope such as a PADRE™ peptide (Epimmune Inc., San Diego, Calif.; see, e.g., Alexander et al., J. Immunol. 2000 164(3); 164(3): 1625-1633; Alexander et al., Immunity 1994 1(9): 751-761 and Alexander et al., Immunol. Res. 1998 18(2): 79-92). An alternative method comprises generating an immune response in an individual against an immunogen of the invention by: administering in vivo to muscle or skin of the individual's body a DNA molecule that comprises a DNA sequence that encodes an immunogen of the invention, the DNA sequence operatively linked to regulatory sequences which control the expression of the DNA sequence; wherein the DNA molecule is taken up by cells, the DNA sequence is expressed in the cells and an immune response is generated against the immunogen (see, e.g., U.S. Pat. No. 5,962,428). Optionally a genetic vaccine facilitator such as anionic lipids; saponins; lectins; estrogenic compounds; hydroxylated lower alkyls; dimethyl sulfoxide; and urea is also administered. In addition, an antiidiotypic antibody can be administered that mimics a protein set forth in FIG. 2, in order to generate a response to the target antigen.

Nucleic Acid Vaccines:

Vaccine compositions of the invention include nucleic acid-mediated modalities. DNA or RNA that encode protein(s) of the invention can be administered to a patient. Genetic immunization methods can be employed to generate prophylactic or therapeutic humoral and cellular immune responses directed against cancer cells expressing FIG. 2 proteins. Constructs comprising DNA encoding a FIG. 2–related protein/immunogen and appropriate regulatory sequences can be injected directly into muscle or skin of an individual, such that the cells of the muscle or skin take-up the construct and express the encoded FIG. 2 protein/immunogen. Alternatively, a vaccine comprises a FIG. 2–related protein. Expression of the FIG. 2–related protein immunogen results in the generation of prophylactic or therapeutic humoral and cellular immunity against cells that bear the FIG. 2–related protein. Various prophylactic and therapeutic genetic immunization techniques known in the art can be used. Nucleic acid-based delivery is described, for instance, in Wolff et. al., Science 247:1465 (1990) as well as U.S. Pat. Nos. 5,580,859; 5,589,466; 5,804,566; 5,739,118; 5,736,524; 5,679,647; WO 98/04720. Examples of DNA-based delivery technologies include “naked DNA”, facilitated (bupivicaine, polymers, peptide-mediated) delivery, cationic lipid complexes, and particle-mediated (“gene gun”) or pressure-mediated delivery (see, e.g., U.S. Pat. No. 5,922,687).

For therapeutic or prophylactic immunization purposes, proteins of the invention can be expressed via viral or bacterial vectors. Various viral gene delivery systems that can be used in the practice of the invention include, but are not limited to, vaccinia, fowlpox, canarypox, adenovirus, influenza, poliovirus, adeno-associated virus, lentivirus, and sindbis virus (see, e.g., Restifo, 1996, Curr. Opin. Immunol. 8:658-663; Tsang et al. J. Natl. Cancer Inst. 87:982-990 (1995)). Non-viral delivery systems can also be employed by introducing naked DNA encoding a FIG. 2–related protein into the patient (e.g., intramuscularly or intradermally) to induce an anti-tumor response.

Vaccinia virus is used, for example, as a vector to express nucleotide sequences that encode the peptides of the invention. Upon introduction into a host, the recombinant vaccinia virus expresses the protein immunogenic peptide, and thereby elicits a host immune response. Vaccinia vectors and methods useful in immunization protocols are described in, e.g., U.S. Pat. No. 4,722,848. Another vector is BCG (Bacille Calmette Guerin). BCG vectors are described in Stover et al., Nature 351:456-460 (1991). A wide variety of other vectors useful for therapeutic administration or immunization of the peptides of the invention, e.g. adeno and adeno-associated virus vectors, retroviral vectors, Salmonella typhi vectors, detoxified anthrax toxin vectors, and the like, will be apparent to those skilled in the art from the description herein.

Thus, gene delivery systems are used to deliver a FIG. 2–related nucleic acid molecule. In one embodiment, the full-length human gene of FIG. 2 cDNA is employed. In another embodiment, FIG. 2 nucleic acid molecules encoding specific cytotoxic T lymphocyte (CTL) and/or antibody epitopes are employed.

Ex Vivo Vaccines

Various ex vivo strategies can also be employed to generate an immune response. One approach involves the use of antigen presenting cells (APCs) such as dendritic cells (DC) to present antigen of the invention to a patient's immune system. Dendritic cells express MHC class I and II molecules, B7 co-stimulator, and IL-12, and are thus highly specialized antigen presenting cells. In prostate cancer, autologous dendritic cells pulsed with peptides of the prostate-specific membrane antigen (PSMA) are being used in a Phase I clinical trial to stimulate prostate cancer patients' immune systems (Tjoa et al., 1996, Prostate 28:65-69; Murphy et al., 1996, Prostate 29:371-380). Thus, dendritic cells can be used to present peptide immunogens of the invention to T cells in the context of MHC class I or II molecules. In one embodiment, autologous dendritic cells are pulsed with immunogenic peptides capable of binding to MHC class I and/or class II molecules. In another embodiment, dendritic cells are pulsed with the complete FIG. 2 protein. Yet another embodiment involves engineering the overexpression of a FIG. 2 gene in dendritic cells using various implementing vectors known in the art, such as adenovirus (Arthur et al., 1997, Cancer Gene Ther. 4:17-25), retrovirus (Henderson et al., 1996, Cancer Res. 56:3763-3770), lentivirus, adeno-associated virus, DNA transfection (Ribas et al., 1997, Cancer Res. 57:2865-2869), or tumor-derived RNA transfection (Ashley et al., 1997, J. Exp. Med. 186:1177-1182). Cells that express proteins of the invention can also be engineered to express immune modulators, such as GM-CSF, and used as immunizing agents.

X.B.) A Protein of FIG. 2 as a Target for Antibody-based Therapy

Proteins of the invention, e.g. FIG. 2, are attractive targets for antibody-based therapeutic strategies. A number of antibody strategies are known in the art for targeting both extracellular and intracellular molecules (see, e.g., complement and ADCC mediated killing as well as the use of intrabodies). Because of the expression profiles of the proteins set forth in FIG. 2, e.g., expressed by cancer cells of various lineages at higher levels compared to corresponding normal cells, systemic administration of proteins in FIG. 2–immunoreactive compositions are prepared that exhibit excellent sensitivity without toxic, non-specific and/or non-target effects caused by binding of the immunoreactive composition to non-target organs and tissues. Antibodies specifically reactive with domains of FIG. 2 proteins are useful to systemically treat cancers that express a protein of FIG. 2, either as conjugates with a toxin or therapeutic agent, or as naked antibodies capable of inhibiting cell proliferation or function.

Antibodies of the invention can be introduced into a patient such that the antibody binds to a protein of the invention and modulate a function, such as an interaction with a binding partner, and consequently mediates destruction of the tumor cells and/or inhibits the growth of the tumor cells. Mechanisms by which such antibodies exert a therapeutic effect can include complement-mediated cytolysis, antibody-dependent cellular cytotoxicity, modulation of the physiological function of proteins of the invention, inhibition of ligand binding or signal transduction pathways, modulation of tumor cell differentiation, alteration of tumor angiogenesis factor profiles, and/or apoptosis.

Those skilled in the art understand that antibodies can be used to specifically target and bind immunogenic molecules such as an immunogenic region of a protein of the invention such as a protein sequence shown in FIG. 2 or FIG. 3. In addition, skilled artisans understand that it is routine to conjugate antibodies to cytotoxic agents (see, e.g., Slevers et al. Blood 93:11 3678-3684 (Jun. 1, 1999)). When cytotoxic and/or therapeutic agents are delivered directly to cells, such as by conjugating them to antibodies specific for a molecule expressed by that cell (e.g. a protein of FIG. 2), the cytotoxic agent will exert its known biological effect (i.e. cytotoxicity) on those cells.

A wide variety of compositions and methods for using antibody-cytotoxic agent conjugates to kill cells are known in the art. In the context of cancers, typical methods entail administering to an animal having a tumor a biologically effective amount of a conjugate comprising a selected cytotoxic and/or therapeutic agent linked to a targeting agent (e.g. an antibody that specifically binds a protein of FIG. 2) that binds to a marker (e.g. a protein of FIG. 2) expressed, accessible to binding or localized on the cell surfaces. A typical embodiment is a method of delivering a cytotoxic and/or therapeutic agent to a cell expressing a FIG. 2 protein, comprising conjugating the cytotoxic agent to an antibody that immunospecifically binds to a protein in FIG. 2 epitope, and, exposing the cell to the antibody-agent conjugate. Another illustrative embodiment is a method of treating an individual suspected of suffering from metastasized cancer, comprising a step of administering parenterally to said individual a pharmaceutical composition comprising a therapeutically effective amount of an antibody conjugated to a cytotoxic and/or therapeutic agent.

Cancer immunotherapy using antibodies o the invention can be done in accordance with various approaches that have been successfully employed in the treatment of other types of cancer, including but not limited to colon cancer (Arlen et al., 1998, Crit. Rev. Immunol. 18:133-138), multiple myeloma (Ozaki et al., 1997, Blood 90:3179-3186, Tsunenari et al., 1997, Blood 90:2437-2444), gastric cancer (Kasprzyk et al., 1992, Cancer Res. 52:2771-2776), B-cell lymphoma (Funakoshi et al., 1996, J. Immunother. Emphasis Tumor Immunol. 19:93-101), leukemia (Zhong et al., 1996, Leuk. Res. 20:581-589), colorectal cancer (Moun et al., 1994, Cancer Res. 54:6160-6166; Velders et al., 1995, Cancer Res. 55:4398-4403), and breast cancer (Shepard et al., 1991, J. Clin. Immunol. 11:117-127). Some therapeutic approaches involve conjugation of naked antibody to a toxin or radioisotope, such as the conjugation of Y⁹¹ or I¹³¹ to anti-CD20 antibodies (e.g., Zevalin™, IDEC Pharmaceuticals Corp. or Bexxar™, Coulter Pharmaceuticals), while others involve co-administration of antibodies and other therapeutic agents, such as Herceptin™ (trastuzumab) with paclitaxel (Genentech, Inc.). The antibodies can be conjugated to a therapeutic agent. To treat prostate cancer, for example, antibodies of the invention can be administered in conjunction with radiation, chemotherapy or hormone ablation. Also, antibodies can be conjugated to a toxin such as calicheamicin (e.g., Mylotarg™, Wyeth-Ayerst, Madison, N.J., a recombinant humanized IgG₄ kappa antibody conjugated to antitumor antibiotic calicheamicin) or a maytansinoid (e.g., taxane-based Tumor-Activated Prodrug, TAP, platform, ImmunoGen, Cambridge, Mass., also see e.g., U.S. Pat. No. 5,416,064).

Although antibody therapy directed to a protein of the invention is useful for all stages of cancer, antibody therapy can be particularly appropriate in advanced or metastatic cancers. Treatment with the antibody therapy of the invention is indicated for patients who have received one or more rounds of chemotherapy. Alternatively, antibody therapy of the invention is combined with a chemotherapeutic or radiation regimen for patients who have not received chemotherapeutic treatment. Additionally, antibody therapy can enable the use of reduced dosages of concomitant chemotherapy, particularly for patients who do not tolerate the toxicity of the chemotherapeutic agent very well. Fan et al. (Cancer Res. 53:4637-4642, 1993), Prewett et al. (International J. of Onco. 9:217-224, 1996), and Hancock et al. (Cancer Res. 51:4575-4580, 1991) describe the use of various antibodies together with chemotherapeutic agents. Treatment with the antibody therapy of the invention is indicated for patients who have received one or more rounds of chemotherapy. Alternatively, antibody therapy of the invention is combined with a chemotherapeutic or radiation regimen for patients who have not received chemotherapeutic treatment. Additionally, antibody therapy can enable the use of reduced dosages of concomitant chemotherapy, particularly for patients who do not tolerate the toxicity of the chemotherapeutic agent very well.

Cancer patients can be evaluated for the presence and level of expression of a gene of FIG. 2, preferably using immunohistochemical assessments of tumor tissue, quantitative imaging of a protein of the invention, or other techniques that reliably indicate the presence and degree of a FIG. 2 protein expression. Immunohistochemical analysis of tumor biopsies or surgical specimens is preferred for this purpose. Methods for immunohistochemical analysis of tumor tissues are well known in the art.

Monoclonal antibodies of the invention that treat cancers (e.g., of a tissue of Table I) include those that initiate a potent immune response against the tumor or those that are directly cytotoxic. In this regard, monoclonal antibodies (mAbs) of the invention can elicit tumor cell lysis by either complement-mediated or antibody-dependent cell cytotoxicity (ADCC) mechanisms, both of which require an intact Fc portion of the immunoglobulin molecule for interaction with effector cell Fc receptor sites on complement proteins. In addition, mAbs of the invention that exert a direct biological effect on tumor growth are useful to treat cancers that express proteins in FIG. 2. Mechanisms by which directly cytotoxic mAbs act include: inhibition of cell growth, modulation of cellular differentiation, modulation of tumor angiogenesis factor profiles, and the induction of apoptosis. The mechanism(s) by which a particular mAbs of the invention exert an anti-tumor effect is evaluated using any number of in vitro assays that evaluate cell death such as ADCC, ADMMC, complement-mediated cell lysis, and so forth, as is generally known in the art.

In some patients, the use of murine or other non-human monoclonal antibodies, or human/mouse chimeric mAbs can induce moderate to strong immune responses against the non-human antibody. This can result in clearance of the antibody from circulation and reduced efficacy. In the most severe cases, such an immune response can lead to the extensive formation of immune complexes which, potentially, can cause renal failure. Accordingly, preferred monoclonal antibodies used in the therapeutic methods of the invention are those that are either fully human or humanized and that bind specifically to the target of proteins in FIG. 2 antigens with high affinity but exhibit low or no antigenicity in the patient.

Therapeutic methods of the invention contemplate the administration of single mAbs as well as combinations, or cocktails, of different mAbs. Such mAb cocktails can have certain advantages inasmuch as they contain mAbs that target different epitopes, exploit different effector mechanisms or combine directly cytotoxic mAbs with mAbs that rely on immune effector functionality. Such mAbs in combination can exhibit synergistic therapeutic effects. In addition, mAbs of the invention can be administered concomitantly with other therapeutic modalities, including but not limited to various chemotherapeutic agents, androgen-blockers, immune modulators (e.g., IL-2, GM-CSF), surgery or radiation. The mAbs of the invention are administered in their “naked” or unconjugated form, or can have a therapeutic agent(s) conjugated to them.

Antibody formulations of the invention are administered via any route capable of delivering the antibodies to a tumor cell. Routes of administration include, but are not limited to, intravenous, intraperitoneal, intramuscular, intratumor, intradermal, and the like. Treatment generally involves repeated administration of an antibody preparation of the invention, via an acceptable route of administration such as intravenous injection (IV), typically at a dose in the range of about 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, or 25 mg/kg body weight. In general, doses in the range of 10-1000 mg mAb per week are effective and well tolerated.

Based on clinical experience with the Herceptin™ mAb in the treatment of metastatic breast cancer, an initial loading dose of approximately 4 mg/kg patient body weight IV, followed by weekly doses of about 2 mg/kg IV of the mAb preparation represents an acceptable dosing regimen. Preferably, the initial loading dose is administered as a 90 minute or longer infusion. The periodic maintenance dose is administered as a 30 minute or longer infusion, provided the initial dose was well tolerated. As appreciated by those of skill in the art, various factors can influence the ideal dose regimen in a particular case. Such factors include, for example, the binding affinity and half life of the Ab or mAbs used, the degree of expression of the protein of the invention in the patient, the extent of circulating shed protein of the invention, the desired steady-state antibody concentration level, frequency of treatment, and the influence of chemotherapeutic or other agents used in combination with the treatment method of the invention, as well as the health status of a particular patient.

Optionally, patients should be evaluated for the levels of a protein of the invention in a given sample (e.g. the levels of circulating FIG. 2 protein antigen and/or proteins of FIG. 2–expressing cells) in order to assist in the determination of the most effective dosing regimen, etc. Such evaluations are also used for monitoring purposes throughout therapy, and are useful to gauge therapeutic success in combination with the evaluation of other parameters (for example, urine cytology and/or ImmunoCyt levels in bladder cancer therapy, or by analogy, serum PSA levels in prostate cancer therapy).

Anti-idiotypic antibodies of the invention can also be used in anti-cancer therapy as a vaccine for inducing an immune response to cells that express a FIG. 2–related protein. In particular, the generation of anti-idiotypic antibodies is well known in the art; this methodology can readily be adapted to generate anti-idiotypic anti-protein of FIG. 2 antibodies that mimic an epitope on a FIG. 2–related protein (see, for example, Wagner et al., 1997, Hybridoma 16: 33-40; Foon et al., 1995, J. Clin. Invest. 96:334-342; Herlyn et al., 1996, Cancer Immunol. Immunother. 43:65-76). Such an anti-idiotypic antibody can be used in cancer vaccine strategies.

X.C.) A Protein of FIG. 2 as a Target for Cellular Immune Responses

Vaccines and methods of preparing vaccines that contain an immunogenically effective amount of one or more HLA-binding peptides as described herein are further embodiments of the invention. Furthermore, vaccines in accordance with the invention encompass compositions of one or more of the claimed peptides. A peptide can be present in a vaccine individually. Alternatively, the peptide can exist as a homopolymer comprising multiple copies of the same peptide, or as a heteropolymer of various peptides. Polymers have the advantage of increased immunological reaction and, where different peptide epitopes are used to make up the polymer, the additional ability to induce antibodies and/or CTLs that react with different antigenic determinants of the pathogenic organism or tumor-related peptide targeted for an immune response. The composition can be a naturally occurring region of an antigen or can be prepared, e.g., recombinantly or by chemical synthesis.

Carriers that can be used with vaccines of the invention are well known in the art, and include, e.g., thyroglobulin, albumins such as human serum albumin, tetanus toxoid, polyamino acids such as poly L-lysine, poly L-glutamic acid, influenza, hepatitis B virus core protein, and the like. The vaccines can contain a physiologically tolerable (i.e., acceptable) diluent such as water, or saline, preferably phosphate buffered saline. The vaccines also typically include an adjuvant. Adjuvants such as incomplete Freund's adjuvant, aluminum phosphate, aluminum hydroxide, or alum are examples of materials well known in the art. Additionally, as disclosed herein, CTL responses can be primed by conjugating peptides of the invention to lipids, such as tripalmitoyl-S-glycerylcysteinlyseryl-serine (P₃CSS). Moreover, an adjuvant such as a synthetic cytosine-phosphorothiolated-guanine-containing (CpG) oligonucleotides has been found to increase CTL responses 10- to 100-fold. (see, e.g. Davila and Celis J. Immunol. 165:539-547 (2000))

Upon immunization with a peptide composition in accordance with the invention, via injection, aerosol, oral, transdermal, transmucosal, intrapleural, intrathecal, or other suitable routes, the immune system of the host responds to the vaccine by producing large amounts of CTLs and/or HTLs specific for the desired antigen. Consequently, the host becomes at least partially immune to later development of cells that express or overexpress an antigen of a protein of FIG. 2, or the host derives at least some therapeutic benefit when the antigen was tumor-associated.

In some embodiments, it may be desirable to combine the class I peptide components with components that induce or facilitate neutralizing antibody and or helper T cell responses directed to the target antigen. A preferred embodiment of such a composition comprises class I and class II epitopes in accordance with the invention. An alternative embodiment of such a composition comprises a class I and/or class II epitope in accordance with the invention, along with a cross reactive HTL epitope such as PADRE™ (Epimmune, San Diego, Calif.) molecule (described e.g., in U.S. Pat. No. 5,736,142).

A vaccine of the invention can also include antigen-presenting cells (APC), such as dendritic cells (DC), as a vehicle to present peptides of the invention. Vaccine compositions can be created in vitro, following dendritic cell mobilization and harvesting, whereby loading of dendritic cells occurs in vitro. For example, dendritic cells are transfected, e.g., with a minigene in accordance with the invention, or are pulsed with peptides. The dendritic cell can then be administered to a patient to elicit immune responses in vivo. Vaccine compositions, either DNA- or peptide-based, can also be administered in vivo in combination with dendritic cell mobilization whereby loading of dendritic cells occurs in vivo.

Preferably, the following principles are utilized when selecting an array of epitopes for inclusion in a polyepitopic composition for use in a vaccine, or for selecting discrete epitopes to be included in a vaccine and/or to be encoded by nucleic acids such as a minigene. It is preferred that each of the following principles be balanced in order to make the selection. The multiple epitopes to be incorporated in a given vaccine composition may be, but need not be, contiguous in sequence in the native antigen from which the epitopes are derived.

-   -   1.) Epitopes are selected which, upon administration, mimic         immune responses that have been observed to be correlated with         tumor clearance. For HLA Class I this includes 3-4 epitopes that         come from at least one tumor associated antigen (TAA). For HLA         Class II a similar rationale is employed; again 3-4 epitopes are         selected from at least one TAA (see, e.g., Rosenberg et al.,         Science 278:1447-1450). Epitopes from one TAA may be used in         combination with epitopes from one or more additional TAAs to         produce a vaccine that targets tumors with varying expression         patterns of frequently-expressed TAAs.     -   2.) Epitopes are selected that have the requisite binding         affinity established to be correlated with immunogenicity: for         HLA Class I an IC₅₀ of 500 nM or less, often 200 nM or less; and         for Class II an IC₅₀ of 1000 nM or less.     -   3.) Sufficient supermotif bearing-peptides, or a sufficient         array of allele-specific motif-bearing peptides, are selected to         give broad population coverage. For example, it is preferable to         have at least 80% population coverage. A Monte Carlo analysis, a         statistical evaluation known in the art, can be employed to         assess the breadth, or redundancy of, population coverage.     -   4.) When selecting epitopes from cancer-related antigens it is         often useful to select analogs because the patient may have         developed tolerance to the native epitope.     -   5.) Of particular relevance are epitopes referred to as “nested         epitopes.” Nested epitopes occur where at least two epitopes         overlap in a given peptide sequence. A nested peptide sequence         can comprise B cell, HLA class I and/or HLA class II epitopes.         When providing nested epitopes, a general objective is to         provide the greatest number of epitopes per sequence. Thus, an         aspect is to avoid providing a peptide that is any longer than         the amino terminus of the amino terminal epitope and the         carboxyl terminus of the carboxyl terminal epitope in the         peptide. When providing a multi-epitopic sequence, such as a         sequence comprising nested epitopes, it is generally important         to screen the sequence in order to insure that it does not have         pathological or other deleterious biological properties.     -   6.) If a polyepitopic protein is created, or when creating a         minigene, an objective is to generate the smallest peptide that         encompasses the epitopes of interest. This principle is similar,         if not the same as that employed when selecting a peptide         comprising nested epitopes. However, with an artificial         polyepitopic peptide, the size minimization objective is         balanced against the need to integrate any spacer sequences         between epitopes in the polyepitopic protein. Spacer amino acid         residues can, for example, be introduced to avoid junctional         epitopes (an epitope recognized by the immune system, not         present in the target antigen, and only created by the man-made         juxtaposition of epitopes), or to facilitate cleavage between         epitopes and thereby enhance epitope presentation. Junctional         epitopes are generally to be avoided because the recipient may         generate an immune response to that non-native epitope. Of         particular concern is a junctional epitope that is a “dominant         epitope.” A dominant epitope may lead to such a zealous response         that immune responses to other epitopes are diminished or         suppressed.     -   7.) Where the sequences of multiple variants of the same target         protein are present, potential peptide epitopes can also be         selected on the basis of their conservancy. For example, a         criterion for conservancy may define that the entire sequence of         an HLA class I binding peptide or the entire 9-mer core of a         class II binding peptide be conserved in a designated percentage         of the sequences evaluated for a specific protein antigen.

X.C.1. Minigene Vaccines

A number of different approaches are available which allow simultaneous delivery of multiple epitopes. Nucleic acids encoding the peptides of the invention are a particularly useful embodiment of the invention. Epitopes for inclusion in a minigene are preferably selected according to the guidelines set forth in the previous section. A preferred means of administering nucleic acids encoding the peptides of the invention uses minigene constructs encoding a peptide comprising one or multiple epitopes of the invention.

The use of multi-epitope minigenes is described below and in, Ishioka et al., J. Immunol. 162:3915-3925, 1999; An, L. and Whitton, J. L., J. Virol. 71:2292, 1997; Thomson, S. A. et al., J. Immunol. 157:822, 1996; Whitton, J. L. et al., J. Virol. 67:348, 1993; Hanke, R. et al., Vaccine 16:426, 1998. For example, a multi-epitope DNA plasmid encoding supermotif- and/or motif-bearing epitopes derived from a protein of the invention, the PADRE® universal helper T cell epitope (or multiple HTL epitopes from a protein of the invention), and an endoplasmic reticulum-translocating signal sequence can be engineered. A vaccine may also comprise epitopes that are derived from other TAAs.

The immunogenicity of a multi-epitopic minigene can be confirmed in transgenic mice to evaluate the magnitude of CTL induction responses against the epitopes tested. Further, the immunogenicity of DNA-encoded epitopes in vivo can be correlated with the in vitro responses of specific CTL lines against target cells transfected with the DNA plasmid. Thus, these experiments can show that the minigene serves: 1.) to generate a CTL response; and, 2.) that the induced CTLs recognized cells expressing the encoded epitopes.

For example, to create a DNA sequence encoding the selected epitopes (minigene) for expression in human cells, the amino acid sequences of the epitopes may be reverse translated. A human codon usage table can be used to guide the codon choice for each amino acid. These epitope-encoding DNA sequences may be directly adjoined, so that when translated, a continuous polypeptide sequence is created. To optimize expression and/or immunogenicity, additional elements can be incorporated into the minigene design. Examples of amino acid sequences that can be reverse translated and included in the minigene sequence include: HLA class I epitopes, HLA class II epitopes, antibody epitopes, a ubiquitination signal sequence, and/or an endoplasmic reticulum targeting signal. In addition, HLA presentation of CTL and HTL epitopes may be improved by including synthetic (e.g. poly-alanine) or naturally-occurring flanking sequences adjacent to the CTL or HTL epitopes; these larger peptides comprising the epitope(s) are within the scope of the invention.

The minigene sequence may be converted to DNA by assembling oligonucleotides that encode the plus and minus strands of the minigene. Overlapping oligonucleotides (30-100 bases long) may be synthesized, phosphorylated, purified and annealed under appropriate conditions using well known techniques. The ends of the oligonucleotides can be joined, for example, using T4 DNA ligase. This synthetic minigene, encoding the epitope polypeptide, can then be cloned into a desired expression vector.

Standard regulatory sequences well known to those of skill in the art are preferably included in the vector to ensure expression in the target cells. Several vector elements are desirable: a promoter with a down-stream cloning site for minigene insertion; a polyadenylation signal for efficient transcription termination; an E. coli origin of replication; and an E. coli selectable marker (e.g. ampicillin or kanamycin resistance). Numerous promoters can be used for this purpose, e.g., the human cytomegalovirus (hCMV) promoter. See, e.g., U.S. Pat. Nos. 5,580,859 and 5,589,466 for other suitable promoter sequences.

Additional vector modifications may be desired to optimize minigene expression and immunogenicity. In some cases, introns are required for efficient gene expression, and one or more synthetic or naturally-occurring introns could be incorporated into the transcribed region of the minigene. The inclusion of mRNA stabilization sequences and sequences for replication in mammalian cells may also be considered for increasing minigene expression.

Once an expression vector is selected, the minigene is cloned into the polylinker region downstream of the promoter. This plasmid is transformed into an appropriate E. coli strain, and DNA is prepared using standard techniques. The orientation and DNA sequence of the minigene, as well as all other elements included in the vector, are confirmed using restriction mapping and DNA sequence analysis. Bacterial cells harboring the correct plasmid can be stored as a master cell bank and a working cell bank.

In addition, immunostimulatory sequences (ISSs or CpGs) appear to play a role in the immunogenicity of DNA vaccines. These sequences may be included in the vector, outside the minigene coding sequence, if desired to enhance immunogenicity.

In some embodiments, a bi-cistronic expression vector which allows production of both the minigene-encoded epitopes and a second protein (included to enhance or decrease immunogenicity) can be used. Examples of proteins or polypeptides that could beneficially enhance the immune response if co-expressed include cytokines (e.g., IL-2, IL-12, GM-CSF), cytokine-inducing molecules (e.g., LeIF), costimulatory molecules, or for HTL responses, pan-DR binding proteins (PADRE™, Epimmune, San Diego, Calif.). Helper (HTL) epitopes can be joined to intracellular targeting signals and expressed separately from expressed CTL epitopes; this allows direction of the HTL epitopes to a cell compartment different than that of the CTL epitopes. If required, this could facilitate more efficient entry of HTL epitopes into the HLA class II pathway, thereby improving HTL induction. In contrast to HTL or CTL induction, specifically decreasing the immune response by co-expression of immunosuppressive molecules (e.g. TGF-β) may be beneficial in certain diseases.

Therapeutic quantities of plasmid DNA can be produced for example, by fermentation in E. coli, followed by purification. Aliquots from the working cell bank are used to inoculate growth medium, and grown to saturation in shaker flasks or a bioreactor according to well-known techniques. Plasmid DNA can be purified using standard bioseparation technologies such as solid phase anion-exchange resins supplied by QIAGEN, Inc. (Valencia, Calif.). If required, supercoiled DNA can be isolated from the open circular and linear forms using gel electrophoresis or other methods.

Purified plasmid DNA can be prepared for injection using a variety of formulations. The simplest of these is reconstitution of lyophilized DNA in sterile phosphate-buffer saline (PBS). This approach, known as “naked DNA,” is currently being used for intramuscular (IM) administration in clinical trials. To maximize the immunotherapeutic effects of minigene DNA vaccines, an alternative method for formulating purified plasmid DNA may be desirable. A variety of methods have been described, and new techniques may become available. Cationic lipids, glycolipids, and fusogenic liposomes can also be used in the formulation (see, e.g., as described by WO 93/24640; Mannino & Gould-Fogerite, BioTechniques 6(7): 682 (1988); U.S. Pat. No. 5,279,833; WO 91/06309; and Felgner, et al., Proc. Nat'l Acad. Sci. USA 84:7413 (1987). In addition, peptides and compounds referred to collectively as protective, interactive, non-condensing compounds (PINC) could also be complexed to purified plasmid DNA to influence variables such as stability, intramuscular dispersion, or trafficking to specific organs or cell types.

Target cell sensitization can be used as a functional assay for expression and HLA class I presentation of minigene-encoded CTL epitopes. For example, the plasmid DNA is introduced into a mammalian cell line that is suitable as a target for standard CTL chromium release assays. The transfection method used will be dependent on the final formulation. Electroporation can be used for “naked” DNA, whereas cationic lipids allow direct in vitro transfection. A plasmid expressing green fluorescent protein (GFP) can be co-transfected to allow enrichment of transfected cells using fluorescence activated cell sorting (FACS). These cells are then chromium-51 (⁵¹Cr) labeled and used as target cells for epitope-specific CTL lines; cytolysis, detected by ⁵¹Cr release, indicates both production of, and HLA presentation of, minigene-encoded CTL epitopes. Expression of HTL epitopes may be evaluated in an analogous manner using assays to assess HTL activity.

In vivo immunogenicity is a second approach for functional testing of minigene DNA formulations. Transgenic mice expressing appropriate human HLA proteins are immunized with the DNA product. The dose and route of administration are formulation dependent (e.g., IM for DNA in PBS, intraperitoneal (i.p.) for lipid-complexed DNA). Twenty-one days after immunization, splenocytes are harvested and restimulated for one week in the presence of peptides encoding each epitope being tested. Thereafter, for CTL effector cells, assays are conducted for cytolysis of peptide-loaded, ⁵¹Cr-labeled target cells using standard techniques. Lysis of target cells that were sensitized by HLA loaded with peptide epitopes, corresponding to minigene-encoded epitopes, demonstrates DNA vaccine function for in vivo induction of CTLs. Immunogenicity of HTL epitopes is confirmed in transgenic mice in an analogous manner.

Alternatively, the nucleic acids can be administered using ballistic delivery as described, for instance, in U.S. Pat. No. 5,204,253. Using this technique, particles comprised solely of DNA are administered. In a further alternative embodiment, DNA can be adhered to particles, such as gold particles.

Minigenes can also be delivered using other bacterial or viral delivery systems well known in the art, e.g., an expression construct encoding epitopes of the invention can be incorporated into a viral vector such as vaccinia.

X.C.2. Combinations of CTL Peptides with Helper Peptides

Vaccine compositions comprising CTL peptides of the invention can be modified, e.g., analoged, to provide desired attributes, such as improved serum half life, broadened population coverage or enhanced immunogenicity.

For instance, the ability of a peptide to induce CTL activity can be enhanced by linking the peptide to a sequence which contains at least one epitope that is capable of inducing a T helper cell response. Although a CTL peptide can be directly linked to a T helper peptide, often CTL epitope/HTL epitope conjugates are linked by a spacer molecule. The spacer is typically comprised of relatively small, neutral molecules, such as amino acids or amino acid mimetics, which are substantially uncharged under physiological conditions. The spacers are typically selected from, e.g., Ala, Gly, or other neutral spacers of nonpolar amino acids or neutral polar amino acids. It will be understood that the optionally present spacer need not be comprised of the same residues and thus may be a hetero- or homo-oligomer. When present, the spacer will usually be at least one or two residues, more usually three to six residues and sometimes 10 or more residues. The CTL peptide epitope can be linked to the T helper peptide epitope either directly or via a spacer either at the amino or carboxy terminus of the CTL peptide. The amino terminus of either the immunogenic peptide or the T helper peptide may be acylated.

In certain embodiments, the T helper peptide is one that is recognized by T helper cells present in a majority of a genetically diverse population. This can be accomplished by selecting peptides that bind to many, most, or all of the HLA class II molecules. Examples of such amino acid bind many HLA Class II molecules include sequences from antigens such as tetanus toxoid at positions 830-843 (QYIKANSKFIGITE; SEQ ID NO: 174), Plasmodium falciparum circumsporozoite (CS) protein at positions 378-398 (DIEKKIAKMEKASSVFNVVNS; SEQ ID NO: 175), and Streptococcus 18 kD protein at positions 116-131 (GAVDSILGGVATYGAA; SEQ ID NO: 176). Other examples include peptides bearing a DR 1-4-7 supermotif, or either of the DR3 motifs.

Alternatively, it is possible to prepare synthetic peptides capable of stimulating T helper lymphocytes, in a loosely HLA-restricted fashion, using amino acid sequences not found in nature (see, e.g., PCT publication WO 95/07707). These synthetic compounds called Pan-DR-binding epitopes (e.g., PADRE™, Epimmune, Inc., San Diego, Calif.) are designed to most preferably bind most HLA-DR (human HLA class II) molecules. For instance, a pan-DR-binding epitope peptide having the formula: aKXVAAWTLKAAa (SEQ ID NO: 177), where “X” is either cyclohexylalanine, phenylalanine, or tyrosine, and a is either D-alanine or L-alanine, has been found to bind to most HLA-DR alleles, and to stimulate the response of T helper lymphocytes from most individuals, regardless of their HLA type. An alternative of a pan-DR binding epitope comprises all “L” natural amino acids and can be provided in the form of nucleic acids that encode the epitope.

HTL peptide epitopes can also be modified to alter their biological properties. For example, they can be modified to include D-amino acids to increase their resistance to proteases and thus extend their serum half life, or they can be conjugated to other molecules such as lipids, proteins, carbohydrates, and the like to increase their biological activity. For example, a T helper peptide can be conjugated to one or more palmitic acid chains at either the amino or carboxyl termini.

X.C.3. Combinations of CTL Peptides with T Cell Priming Agents

In some embodiments it may be desirable to include in the pharmaceutical compositions of the invention at least one component which primes B lymphocytes or T lymphocytes. Lipids have been identified as agents capable of priming CTL in vivo. For example, palmitic acid residues can be attached to the ε- and α-amino groups of a lysine residue and then linked, e.g., via one or more linking residues such as Gly, Gly-Gly-, Ser, Ser-Ser, or the like, to an immunogenic peptide. The lipidated peptide can then be administered either directly in a micelle or particle, incorporated into a liposome, or emulsified in an adjuvant, e.g. incomplete Freund's adjuvant. In a preferred embodiment, a particularly effective immunogenic composition comprises palmitic acid attached to ε- and α-amino groups of Lys, which is attached via linkage, e.g., Ser-Ser, to the amino terminus of the immunogenic peptide.

As another example of lipid priming of CTL responses, E. coli lipoproteins, such as tripalmitoyl-S-glycerylcysteinlyseryl-serine (P₃CSS) can be used to prime virus specific CTL when covalently attached to an appropriate peptide (see, e.g., Deres, et al., Nature 342:561, 1989). Peptides of the invention can be coupled to P₃CSS, for example, and the lipopeptide administered to an individual to specifically prime an immune response to the target antigen. Moreover, because the induction of neutralizing antibodies can also be primed with P₃CSS-conjugated epitopes, two such compositions can be combined to more effectively elicit both humoral and cell-mediated responses.

X.C.4. Vaccine Compositions Comprising DC Pulsed with CTL and/or HTL Peptides

An embodiment of a vaccine composition in accordance with the invention comprises ex vivo administration of a cocktail of epitope-bearing peptides to PBMC, or isolated DC therefrom, from the patient's blood. A pharmaceutical to facilitate harvesting of DC can be used, such as Progenipoietin™ (Pharmacia-Monsanto, St. Louis, Mo.) or GM-CSF/IL-4. After pulsing the DC with peptides and prior to reinfusion into patients, the DC are washed to remove unbound peptides. In this embodiment, a vaccine comprises peptide-pulsed DCs which present the pulsed peptide epitopes complexed with HLA molecules on their surfaces.

The DC can be pulsed ex vivo with a cocktail of peptides, some of which stimulate CTL responses to a protein of FIG. 2. Optionally, a helper T cell (HTL) peptide, such as a natural or artificial loosely restricted HLA Class II peptide, can be included to facilitate the CTL response. Thus, a vaccine in accordance with the invention is used to treat a cancer which expresses or overexpresses a protein of FIG. 2.

X.D. Adoptive Immunotherapy

Antigenic peptides of the invention, e.g., peptides derived from a protein of FIG. 2, are used to elicit a CTL and/or HTL response ex vivo, as well. The resulting CTL or HTL cells, can be used to treat tumors in patients that do not respond to other conventional forms of therapy, or will not respond to a therapeutic vaccine peptide or nucleic acid in accordance with the invention. Ex vivo CTL or HTL responses to a particular antigen are induced by incubating in tissue culture the patient's, or genetically compatible, CTL or HTL precursor cells together with a source of antigen-presenting cells (APC), such as dendritic cells, and the appropriate immunogenic peptide. After an appropriate incubation time (typically about 7-28 days), in which the precursor cells are activated and expanded into effector cells, the cells are infused back into the patient, where they will destroy (CTL) or facilitate destruction (HTL) of their specific target cell (e.g., a tumor cell). Transfected dendritic cells may also be used as antigen presenting cells.

X.E. Administration of Vaccines for Therapeutic or Prophylactic Purposes

Pharmaceutical and vaccine compositions of the invention are typically used to treat and/or prevent a cancer that expresses or overexpresses a FIG. 2 protein. In therapeutic applications, peptide and/or nucleic acid compositions are administered to a patient in an amount sufficient to elicit an effective B cell, CTL and/or HTL response to the antigen and to cure or at least partially arrest or slow symptoms and/or complications. An amount adequate to accomplish this is defined as “therapeutically effective dose.” Amounts effective for this use will depend on, e.g., the particular composition administered, the manner of administration, the stage and severity of the disease being treated, the weight and general state of health of the patient, and the judgment of the prescribing physician.

For pharmaceutical compositions, the immunogenic peptides of the invention, or DNA encoding them, are generally administered to an individual already bearing a tumor that expresses a protein of FIG. 2. The peptides or DNA encoding them can be administered individually or as fusions of one or more peptide sequences. Patients can be treated with the immunogenic peptides separately or in conjunction with other treatments, such as surgery, as appropriate.

For therapeutic use, administration should generally begin at the first diagnosis of a protein of FIG. 2–associated cancer. This is followed by boosting doses until at least symptoms are substantially abated and for a period thereafter. The embodiment of the vaccine composition (i.e., including, but not limited to embodiments such as peptide cocktails, polyepitopic polypeptides, minigenes, or TAA-specific CTLs or pulsed dendritic cells) delivered to the patient may vary according to the stage of the disease or the patient's health status. For example, in a patient with a tumor that expresses a protein of FIG. 2, a vaccine comprising CTLs specific for the respective protein of FIG. 2 may be more efficacious in killing tumor cells in patient with advanced disease than alternative embodiments.

It is generally important to provide an amount of the peptide epitope delivered by a mode of administration sufficient to effectively stimulate a cytotoxic T cell response; compositions which stimulate helper T cell responses can also be given in accordance with this embodiment of the invention.

The dosage for an initial therapeutic immunization generally occurs in a unit dosage range where the lower value is about 1, 5, 50, 500, or 1,000 μg and the higher value is about 10,000; 20,000; 30,000; or 50,000 μg. Dosage values for a human typically range from about 500 μg to about 50,000 μg per 70 kilogram patient. Boosting dosages of between about 1.0 μg to about 50,000 μg of peptide pursuant to a boosting regimen over weeks to months may be administered depending upon the patient's response and condition as determined by measuring the specific activity of CTL and HTL obtained from the patient's blood. Administration should continue until at least clinical symptoms or laboratory tests indicate that the neoplasia, has been eliminated or reduced and for a period thereafter. The dosages, routes of administration, and dose schedules are adjusted in accordance with methodologies known in the art.

In certain embodiments, the peptides and compositions of the present invention are employed in serious disease states, that is, life-threatening or potentially life threatening situations. In such cases, as a result of the minimal amounts of extraneous substances and the relative nontoxic nature of the peptides in preferred compositions of the invention, it is possible and may be felt desirable by the treating physician to administer substantial excesses of these peptide compositions relative to these stated dosage amounts.

The vaccine compositions of the invention can also be used purely as prophylactic agents. Generally the dosages for an initial prophylactic immunization generally occurs in a unit dosage range where the lower value is about 1, 5, 50, 500, or 1000 μg and the higher value is about 10,000; 20,000; 30,000; or 50,000 μg. Dosage values for a human typically range from about 500 μg to about 50,000 μg per 70 kilogram patient. This is followed by boosting dosages of between about 1.0 μg to about 50,000 μg of peptide administered at defined intervals from about four weeks to six months after the initial administration of vaccine. The immunogenicity of the vaccine can be assessed by measuring the specific activity of CTL and HTL obtained from a sample of the patient's blood.

The pharmaceutical compositions for therapeutic treatment are intended for parenteral, topical, oral, nasal, intrathecal, or local (e.g. as a cream or topical ointment) administration. Preferably, the pharmaceutical compositions are administered parentally, e.g., intravenously, subcutaneously, intradermally, or intramuscularly. Thus, the invention provides compositions for parenteral administration which comprise a solution of the immunogenic peptides dissolved or suspended in an acceptable carrier, preferably an aqueous carrier.

A variety of aqueous carriers may be used, e.g., water, buffered water, 0.8% saline, 0.3% glycine, hyaluronic acid and the like. These compositions may be sterilized by conventional, well-known sterilization techniques, or may be sterile filtered. The resulting aqueous solutions may be packaged for use as is, or lyophilized, the lyophilized preparation being combined with a sterile solution prior to administration.

The compositions may contain pharmaceutically acceptable auxiliary substances as required to approximate physiological conditions, such as pH-adjusting and buffering agents, tonicity adjusting agents, wetting agents, preservatives, and the like, for example, sodium acetate, sodium lactate, sodium chloride, potassium chloride, calcium chloride, sorbitan monolaurate, triethanolamine oleate, etc.

The concentration of peptides of the invention in the pharmaceutical formulations can vary widely, i.e., from less than about 0.1%, usually at or at least about 2% to as much as 20% to 50% or more by weight, and will be selected primarily by fluid volumes, viscosities, etc., in accordance with the particular mode of administration selected.

A human unit dose form of a composition is typically included in a pharmaceutical composition that comprises a human unit dose of an acceptable carrier, in one embodiment an aqueous carrier, and is administered in a volume/quantity that is known by those of skill in the art to be used for administration of such compositions to humans (see, e.g., Remington's Pharmaceutical Sciences, 17^(th) Edition, A. Gennaro, Editor, Mack Publishing Co., Easton, Pa., 1985). For example a peptide dose for initial immunization can be from about 1 to about 50,000 μg, generally 100-5,000 μg, for a 70 kg patient. For example, for nucleic acids an initial immunization may be performed using an expression vector in the form of naked nucleic acid administered IM (or SC or ID) in the amounts of 0.5-5 mg at multiple sites. The nucleic acid (0.1 to 1000 μg) can also be administered using a gene gun. Following an incubation period of 3-4 weeks, a booster dose is then administered. The booster can be recombinant fowlpox virus administered at a dose of 5-10⁷ to 5×10⁹ pfu.

For antibodies, a treatment generally involves repeated administration of the antibody preparation, via an acceptable route of administration such as intravenous injection (IV), typically at a dose in the range of about 0.1 to about 10 mg/kg body weight. In general, doses in the range of 10-500 mg mAb per week are effective and well tolerated. Moreover, an initial loading dose of approximately 4 mg/kg patient body weight IV, followed by weekly doses of about 2 mg/kg IV of the anti-FIG. 2 protein mAb preparation represents an acceptable dosing regimen. As appreciated by those of skill in the art, various factors can influence the ideal dose in a particular case. Such factors include, for example, half life of a composition, the binding affinity of an Ab, the immunogenicity of a substance, the degree of expression of the protein of the invention in the patient, the extent of circulating shed of protein of the invention antigen, the desired steady-state concentration level, frequency of treatment, and the influence of chemotherapeutic or other agents used in combination with the treatment method of the invention, as well as the health status of a particular patient. Non-limiting preferred human unit doses are, for example, 500 μg-1 mg, 1 mg-50 mg, 50 mg-100 mg, 100 mg-200 mg, 200 mg-300 mg, 400 mg-500 mg, 500 mg-600 mg, 600 mg-700 mg, 700 mg-800 mg, 800 mg-900 mg, 900 mg-1 g, or 1 mg-700 mg. In certain embodiments, the dose is in a range of 2-5 mg/kg body weight, e.g., with follow on weekly doses of 1-3 mg/kg; 0.5 mg, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 mg/kg body weight followed, e.g., in two, three or four weeks by weekly doses; 0.5-10 mg/kg body weight, e.g., followed in two, three or four weeks by weekly doses; 225, 250, 275, 300, 325, 350, 375, 400 mg m² of body area weekly; 1-600 mg m² of body area weekly; 225-400 mg m² of body area weekly; these does can be followed by weekly doses for 2, 3, 4, 5, 6, 7, 8, 9, 19, 11, 12 or more weeks.

In one embodiment, human unit dose forms of polynucleotides comprise a suitable dosage range or effective amount that provides any therapeutic effect. As appreciated by one of ordinary skill in the art a therapeutic effect depends on a number of factors, including the sequence of the polynucleotide, molecular weight of the polynucleotide and route of administration. Dosages are generally selected by the physician or other health care professional in accordance with a variety of parameters known in the art, such as severity of symptoms, history of the patient and the like. Generally, for a polynucleotide of about 20 bases, a dosage range may be selected from, for example, an independently selected lower limit such as about 0.1, 0.25, 0.5, 1, 2, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300, 400 or 500 mg/kg up to an independently selected upper limit, greater than the lower limit, of about 60, 80, 100, 200, 300, 400, 500, 750, 1000, 1500, 2000, 3000, 4000, 5000, 6000, 7000, 8000, 9000 or 10,000 mg/kg. For example, a dose may be about any of the following: 0.1 to 100 mg/kg, 0.1 to 50 mg/kg, 0.1 to 25 mg/kg, 0.1 to 10 mg/kg, 1 to 500 mg/kg, 100 to 400 mg/kg, 200 to 300 mg/kg, 1 to 100 mg/kg, 100 to 200 mg/kg, 300 to 400 mg/kg, 400 to 500 mg/kg, 500 to 1000 mg/kg, 500 to 5000 mg/kg, or 500 to 10,000 mg/kg. Generally, parenteral routes of administration may require higher doses of polynucleotide compared to more direct application to the nucleotide to diseased tissue, as do polynucleotides of increasing length.

In one embodiment, human unit dose forms of T-cells comprise a suitable dosage range or effective amount that provides any therapeutic effect. As appreciated by one of ordinary skill in the art, a therapeutic effect depends on a number of factors. Dosages are generally selected by the physician or other health care professional in accordance with a variety of parameters known in the art, such as severity of symptoms, history of the patient and the like. A dose may be about 10⁴ cells to about 10⁶ cells, about 10⁶ cells to about 10⁸ cells, about 10⁸ to about 10¹¹ cells, or about 10⁸ to about 5×10¹⁰ cells. A dose may also about 10⁶ cells/m² to about 10¹⁰ cells/m², or about 10⁶ cells/m² to about 10⁸ cells/m².

Proteins(s) of the invention, and/or nucleic acids encoding the protein(s), can also be administered via liposomes, which may also serve to: 1) target the proteins(s) to a particular tissue, such as lymphoid tissue; 2) to target selectively to diseases cells; or, 3) to increase the half-life of the peptide composition. Liposomes include emulsions, foams, micelles, insoluble monolayers, liquid crystals, phospholipid dispersions, lamellar layers and the like. In these preparations, the peptide to be delivered is incorporated as part of a liposome, alone or in conjunction with a molecule which binds to a receptor prevalent among lymphoid cells, such as monoclonal antibodies which bind to the CD45 antigen, or with other therapeutic or immunogenic compositions. Thus, liposomes either filled or decorated with a desired peptide of the invention can be directed to the site of lymphoid cells, where the liposomes then deliver the peptide compositions. Liposomes for use in accordance with the invention are formed from standard vesicle-forming lipids, which generally include neutral and negatively charged phospholipids and a sterol, such as cholesterol. The selection of lipids is generally guided by consideration of, e.g., liposome size, acid lability and stability of the liposomes in the blood stream. A variety of methods are available for preparing liposomes, as described in, e.g., Szoka, et al., Ann. Rev. Biophys. Bioeng. 9:467 (1980), and U.S. Pat. Nos. 4,235,871, 4,501,728, 4,837,028, and 5,019,369.

For targeting cells of the immune system, a ligand to be incorporated into the liposome can include, e.g., antibodies or fragments thereof specific for cell surface determinants of the desired immune system cells. A liposome suspension containing a peptide may be administered intravenously, locally, topically, etc. in a dose which varies according to, inter alia, the manner of administration, the peptide being delivered, and the stage of the disease being treated.

For solid compositions, conventional nontoxic solid carriers may be used which include, for example, pharmaceutical grades of mannitol, lactose, starch, magnesium stearate, sodium saccharin, talcum, cellulose, glucose, sucrose, magnesium carbonate, and the like. For oral administration, a pharmaceutically acceptable nontoxic composition is formed by incorporating any of the normally employed excipients, such as those carriers previously listed, and generally 10-95% of active ingredient, that is, one or more peptides of the invention, and more preferably at a concentration of 25%-75%.

For aerosol administration, immunogenic peptides are preferably supplied in finely divided form along with a surfactant and propellant. Typical percentages of peptides are about 0.01%-20% by weight, preferably about 1%-10%. The surfactant must, of course, be nontoxic, and preferably soluble in the propellant. Representative of such agents are the esters or partial esters of fatty acids containing from about 6 to 22 carbon atoms, such as caproic, octanoic, lauric, palmitic, stearic, linoleic, linolenic, olesteric and oleic acids with an aliphatic polyhydric alcohol or its cyclic anhydride. Mixed esters, such as mixed or natural glycerides may be employed. The surfactant may constitute about 0.1%-20% by weight of the composition, preferably about 0.25-5%. The balance of the composition is ordinarily propellant. A carrier can also be included, as desired, as with, e.g., lecithin for intranasal delivery.

XI.) Diagnostic and Prognostic Embodiments of the Invention.

As disclosed herein, polynucleotides, polypeptides, reactive cytotoxic T cells (CTL), reactive helper T cells (HTL) and anti-polypeptide antibodies of the invention are used in well known diagnostic, prognostic and therapeutic assays that examine conditions associated with dysregulated cell growth such as cancer, in particular the cancers listed in Table I (see, e.g., both its specific pattern of tissue expression as well as its overexpression in certain cancers as described for example in Example 4).

Proteins of FIG. 2 can be analogized to the prostate associated antigen PSA, the archetypal marker that has been used by medical practitioners for years to identify and monitor the presence of prostate cancer (see, e.g., Merrill et al., J. Urol. 163(2): 503-5120 (2000); Polascik et al., J. Urol. August; 162(2):293-306 (1999) and Fortier et al., J. Nat. Cancer Inst. 91(19): 1635-1640(1999)). A variety of other diagnostic markers are also used in similar contexts including p53 and K-ras (see, e.g., Tulchinsky et al., Int J Mol Med 1999 July 4(1):99-102 and Minimoto et al., Cancer Detect Prev 2000; 24(1):1-12). Therefore, this disclosure of FIG. 2 polynucleotides and polypeptides (as well as FIG. 2–related polynucleotide probes and anti-FIG. 2 protein antibodies used to identify the presence of these molecules) and their properties allows skilled artisans to utilize these molecules in methods that are analogous to those used, for example, in a variety of diagnostic assays directed to examining conditions associated with cancer.

Typical embodiments of diagnostic methods, which utilize the polynucleotides, polypeptides, reactive T cells and antibodies of the invention, are analogous to those methods from well-established diagnostic assays which employ, e.g., PSA polynucleotides, polypeptides, reactive T cells and antibodies. For example, just as PSA polynucleotides are used as probes (for example in Northern analysis, see, e.g., Sharief et al., Biochem. Mol. Biol. Int. 33(3):567-74(1994)) and primers (for example in PCR analysis, see, e.g., Okegawa et al., J. Urol. 163(4): 1189-1190 (2000)) to observe the presence and/or the level of PSA mRNAs in methods of monitoring PSA overexpression or the metastasis of prostate cancers, the FIG. 2 polynucleotides described herein can be utilized in the same way to detect the respective FIG. 2 protein overexpression or the metastasis of prostate and other cancers expressing this gene. Alternatively, just as PSA polypeptides are used to generate antibodies specific for PSA which can then be used to observe the presence and/or the level of PSA proteins in methods to monitor PSA protein overexpression (see, e.g., Stephan et al., Urology 55(4):560-3 (2000)) or the metastasis of prostate cells (see, e.g., Alanen et al., Pathol. Res. Pract. 192(3):233-7 (1996)), the FIG. 2 polypeptides described herein can be utilized to generate antibodies for use in detecting the respective proteins of FIG. 2 overexpression or the metastasis of prostate cells and cells of other cancers expressing this gene.

Specifically, because metastases involves the movement of cancer cells from an organ of origin (such as the lung or prostate gland etc.) to a different area of the body (such as a lymph node), assays which examine a biological sample for the presence of cells expressing FIG. 2 polynucleotides and/or polypeptides can be used to provide evidence of metastasis. For example, when a biological sample from tissue that does not normally contain gene or protein of FIG. 2–expressing cells (e.g., a lymph node) is found to contain a protein of FIG. 2–expressing cells, this finding is indicative of metastasis.

Alternatively polynucleotides and/or polypeptides of the invention can be used to provide evidence of cancer, for example, when cells in a biological sample that do not normally express FIG. 2 genes or express FIG. 2 genes at a different level are found to express FIG. 2 genes or have an increased expression of FIG. 2 genes (see, e.g., the expression in the cancers of tissues listed in Table I and in patient samples etc. shown in the accompanying Figures). In such assays, artisans may further wish to generate supplementary evidence of metastasis by testing the biological sample for the presence of a second tissue restricted marker (in addition to a protein of FIG. 2) such as PSA, PSCA etc. (see, e.g., Alanen et al., Pathol. Res. Pract. 192(3): 233-237 (1996)).

Just as PSA polynucleotide fragments and polynucleotide variants are employed by skilled artisans for use in methods of monitoring PSA, a gene of FIG. 2 polynucleotide fragments and polynucleotide variants are used in an analogous manner. In particular, typical PSA polynucleotides used in methods of monitoring PSA are probes or primers which consist of fragments of the PSA cDNA sequence. Illustrating this, primers used to PCR amplify a PSA polynucleotide must include less than the whole PSA sequence to function in the polymerase chain reaction. In the context of such PCR reactions, skilled artisans generally create a variety of different polynucleotide fragments that can be used as primers in order to amplify different portions of a polynucleotide of interest or to optimize amplification reactions (see, e.g., Caetano-Anolles, G. Biotechniques 25(3): 472-476, 478-480 (1998); Robertson et al., Methods Mot. Biol. 98:121-154 (1998)). An additional illustration of the use of such fragments is provided in Example 4, where a gene of FIG. 2 polynucleotide fragments are used as a probe to show the expression of respective gene of FIG. 2 RNAs in cancer cells. In addition, variant polynucleotide sequences are typically used as primers and probes for the corresponding mRNAs in PCR and Northern analyses (see, e.g., Sawai et al., Fetal Diagn. Ther. 1996 November-December 11(6):407-13 and Current Protocols In Molecular Biology, Volume 2, Unit 2, Frederick M. Ausubel et al. eds., 1995)). Polynucleotide fragments and variants are useful in this context where they are capable of binding to a target polynucleotide sequence (e.g., a FIG. 2 polynucleotide or variant thereof) under conditions of high stringency.

Furthermore, PSA polypeptides which contain an epitope that can be recognized by an antibody or T cell that specifically binds to that epitope are used in methods of monitoring PSA. Polypeptide fragments, polypeptide analogs or variants of a protein of FIG. 2 can also be used in an analogous manner. This practice of using polypeptide fragments or polypeptide variants to generate antibodies (such as anti-PSA antibodies or T cells) is typical in the art with a wide variety of systems such as fusion proteins being used by practitioners (see, e.g., Current Protocols In Molecular Biology, Volume 2, Unit 16, Frederick M. Ausubel et al. eds., 1995). In this context, each epitope(s) functions to provide the architecture with which an antibody or T cell is reactive. Typically, skilled artisans create a variety of different polypeptide fragments that can be used in order to generate immune responses specific for different portions of a polypeptide of interest (see, e.g., U.S. Pat. No. 5,840,501 and U.S. Pat. No. 5,939,533). For example it may be preferable to utilize a polypeptide comprising one of the biological motifs of a protein of FIG. 2 discussed herein or a motif-bearing subsequence which is readily identified by one of skill in the art based on motifs available in the art. Polypeptide fragments, variants or analogs are typically useful in this context as long as they comprise an epitope capable of generating an antibody or T cell specific for a target polypeptide sequence (e.g. a protein of FIG. 2).

As shown herein, the FIG. 2 polynucleotides and polypeptides (as well as the FIG. 2 polynucleotide probes and anti-proteins of FIG. 2 antibodies or T cells used to identify the presence of these molecules) exhibit specific properties that make them useful in diagnosing cancers such as those listed in Table I. Diagnostic assays that measure the presence of gene of FIG. 2 gene products, in order to evaluate the presence or onset of a disease condition described herein, such as prostate cancer, are used to identify patients for preventive measures or further monitoring, as has been done so successfully with PSA. Moreover, these materials satisfy a need in the art for molecules having similar or complementary characteristics to PSA in situations where, for example, a definite diagnosis of metastasis of prostatic origin cannot be made on the basis of a test for PSA alone (see, e.g., Alanen et al., Pathol. Res. Pract. 192(3): 233-237 (1996)), and consequently, materials such as FIG. 2 polynucleotides and polypeptides (as well as the gene of FIG. 2 polynucleotide probes and anti-proteins of FIG. 2 antibodies used to identify the presence of these molecules) need to be employed to confirm a metastases of prostatic origin.

Finally, in addition to their use in diagnostic assays, the FIG. 2 polynucleotides disclosed herein have a number of other utilities such as their use in the identification of oncogenetic associated chromosomal abnormalities in the chromosomal region to which a FIG. 2 gene maps (see Example 3 below). Moreover, in addition to their use in diagnostic assays, the FIG. 2–related proteins and polynucleotides disclosed herein have other utilities such as their use in the forensic analysis of tissues of unknown origin (see, e.g., Takahama K Forensic Sci Int 1996 Jun. 28; 80(1-2): 63-9).

Additionally, FIG. 2–related proteins or polynucleotides of the invention can be used to treat a pathologic condition characterized by the over-expression of FIG. 2 proteins. For example, the amino acid or nucleic acid sequences in FIG. 2 or FIG. 3, or fragments of either, can be used to generate an immune response to a protein of FIG. 2 antigen. Antibodies or other molecules that react with proteins of the invention FIG. 2 can be used to modulate the function of this molecule, and thereby provide a therapeutic benefit.

XII.) Inhibition of the Function of a Protein in the Invention

The invention includes various methods and compositions for inhibiting the binding of proteins in FIG. 2 to its binding partner or its association with other protein(s) as well as methods for inhibiting the function of proteins in FIG. 2.

XII.A.) Inhibition of a Protein of FIG. 2 with Intracellular Antibodies

In one approach, a recombinant vector that encodes single chain antibodies that specifically bind to a FIG. 2 protein are introduced into proteins of FIG. 2 expressing cells via gene transfer technologies. Accordingly, the encoded single chain anti-protein of FIG. 2 antibodies are expressed intracellularly, and bind to the respective FIG. 2 protein, and thereby inhibits its function. Methods for engineering such intracellular single chain antibodies are well known. Such intracellular antibodies, also known as “intrabodies”, are specifically targeted to a particular compartment within the cell, providing control over where the inhibitory activity of the treatment is focused. This technology has been successfully applied in the art (for review, see Richardson and Marasco, 1995, TIBTECH vol. 13). Intrabodies have been shown to virtually eliminate the expression of otherwise abundant cell surface receptors (see, e.g., Richardson et al., 1995, Proc. Natl. Acad. Sci. USA 92: 3137-3141; Beerli et al., 1994, J. Biol. Chem. 289: 23931-23936; Deshane et al., 1994, Gene Ther. 1: 332-337).

Single chain antibodies comprise the variable domains of the heavy and light chain joined by a flexible linker polypeptide, and are expressed as a single polypeptide. Optionally, single chain antibodies are expressed as a single chain variable region fragment joined to the light chain constant region. Well-known intracellular trafficking signals are engineered into recombinant polynucleotide vectors encoding such single chain antibodies in order to precisely target the intrabody to the desired intracellular compartment. For example, intrabodies targeted to the endoplasmic reticulum (ER) are engineered to incorporate a leader peptide and, optionally, a C-terminal ER retention signal, such as the KDEL amino acid motif. Intrabodies intended to exert activity in the nucleus are engineered to include a nuclear localization signal. Lipid moieties are joined to intrabodies in order to tether the intrabody to the cytosolic side of the plasma membrane. Intrabodies can also be targeted to exert function in the cytosol. For example, cytosolic intrabodies are used to sequester factors within the cytosol, thereby preventing them from being transported to their natural cellular destination.

In one embodiment, intrabodies are used to capture proteins of FIG. 2 in the nucleus, thereby preventing the activity of that protein(s) within the nucleus. Nuclear targeting signals are engineered into such FIG. 2–related intrabodies in order to achieve the desired targeting. Such FIG. 2–related intrabodies are designed to bind specifically to a particular FIG. 2 protein domain. In another embodiment, cytosolic intrabodies that specifically bind to a FIG. 2 protein are used to prevent the protein in FIG. 2 from gaining access to the nucleus, thereby preventing it from exerting any biological activity within the nucleus (e.g., preventing proteins of FIG. 2 from forming transcription complexes with other factors).

In order to specifically direct the expression of such intrabodies to particular cells, the transcription of the intrabody is placed under the regulatory control of an appropriate tumor-specific promoter and/or enhancer. In order to target intrabody expression specifically to prostate, for example, the PSA promoter and/or promoter/enhancer can be utilized (See, for example, U.S. Pat. No. 5,919,652 issued 6 Jul. 1999).

XII.B.) Inhibition of a Protein of FIG. 2 with Recombinant Proteins

In another approach, recombinant molecules bind to a FIG. 2 protein and thereby inhibit the function of a protein of FIG. 2. For example, these recombinant molecules prevent or inhibit FIG. 2 proteins from accessing/binding to its binding partner(s) or associating with other protein(s). Such recombinant molecules can, for example, contain the reactive part(s) of an antibody molecule specific for a protein of FIG. 2. In a particular embodiment, the FIG. 2 protein binding domain of a corresponding binding partner is engineered into a dimeric fusion protein, whereby the fusion protein comprises two protein of FIG. 2 ligand binding domains linked to the Fc portion of a human IgG, such as human IgG1. Such IgG portion can contain, for example, the C_(H)2 and C_(H)3 domains and the hinge region, but not the C_(H)1 domain. Such dimeric fusion proteins are administered in soluble form to patients suffering from a cancer associated with the expression of proteins of the invention, see, e.g., FIG. 2, whereby the dimeric fusion protein specifically binds to a FIG. 2 protein and blocks the interaction of a FIG. 2 protein with one or more binding partners. Such dimeric fusion proteins are further combined into multimeric proteins using known antibody linking technologies.

XII.C.) Inhibition of Transcription or Translation in Accordance with the Invention

The present invention also comprises various methods and compositions for inhibiting the transcription of a FIG. 2 gene. Similarly, the invention also provides methods and compositions for inhibiting the translation of the genes in FIG. 2–related mRNA into protein.

In one approach, a method of inhibiting the transcription of a FIG. 2 gene comprises contacting the FIG. 2 gene with a respective FIG. 2 antisense polynucleotide. In another approach, a method of inhibiting gene of FIG. 2–related mRNA translation comprises contacting a gene of FIG. 2–related mRNA with an antisense polynucleotide. In another approach, a gene of FIG. 2 specific ribozyme is used to cleave a gene of FIG. 2–related message, thereby inhibiting translation. Such antisense and ribozyme based methods can also be directed to the regulatory regions of a FIG. 2 gene, such as a promoter and/or enhancer element for a gene of FIG. 2. Similarly, proteins capable of inhibiting agene of FIG. 2 transcription factor are used to inhibit the gene of FIG. 2 mRNA transcription. The various polynucleotides and compositions useful in the aforementioned methods have been described above. The use of antisense and ribozyme molecules to inhibit transcription and translation is well known in the art.

Other factors that inhibit the transcription of a FIG. 2 gene by interfering with that gene's transcriptional activation are also useful to treat cancers expressing genes of FIG. 2. Similarly, factors that interfere with a gene of FIG. 2 gene processing are useful to treat cancers that express genes of FIG. 2. Cancer treatment methods utilizing such factors are also within the scope of the invention.

XII.D.) General Considerations for Therapeutic Strategies

Gene transfer and gene therapy technologies can be used to deliver therapeutic polynucleotide molecules to tumor cells synthesizing proteins of the invention, see, e.g., FIG. 2, (e.g., antisense, ribozyme, polynucleotides encoding intrabodies and other gene/protein of FIG. 2 inhibitory molecules). A number of gene therapy approaches are known in the art. Recombinant vectors encoding FIG. 2 antisense polynucleotides, ribozymes, factors capable of interfering with transcription of a gene of FIG. 2, and so forth, can be delivered to target tumor cells using such gene therapy approaches.

The above therapeutic approaches can be combined with any one of a wide variety of surgical, chemotherapy or radiation therapy regimens. The therapeutic approaches of the invention can enable the use of reduced dosages of chemotherapy (or other therapies) and/or less frequent administration, an advantage for all patients and particularly for those that do not tolerate the toxicity of the chemotherapeutic agent well.

The anti-tumor activity of a particular composition (e.g., antisense, ribozyme, intrabody), or a combination of such compositions, can be evaluated using various in vitro and in vivo assay systems. In vitro assays that evaluate therapeutic activity include cell growth assays, soft agar assays and other assays indicative of tumor promoting activity, binding assays capable of determining the extent to which a therapeutic composition will inhibit the binding of a protein of FIG. 2 to one or more of its binding partners, etc.

In vivo, the effects of a therapeutic composition of the invention can be evaluated in a suitable animal model. For example, xenogenic prostate cancer models can be used, wherein human prostate cancer explants or passaged xenograft tissues are introduced into immune compromised animals, such as nude or SCID mice (Klein et al., 1997, Nature Medicine 3: 402-408). For example, PCT Patent Application WO98/16628 and U.S. Pat. No. 6,107,540 describe various xenograft models of human prostate cancer capable of recapitulating the development of primary tumors, micrometastasis, and the formation of osteoblastic metastases characteristic of late stage disease. Efficacy can be predicted using assays that measure inhibition of tumor formation, tumor regression or metastasis, and the like.

In vivo assays that evaluate the promotion of apoptosis are useful in evaluating therapeutic compositions. In one embodiment, xenografts from tumor bearing mice treated with the therapeutic composition can be examined for the presence of apoptotic foci and compared to untreated control xenograft-bearing mice. The extent to which apoptotic foci are found in the tumors of the treated mice provides an indication of the therapeutic efficacy of the composition.

The therapeutic compositions used in the practice of the foregoing methods can be formulated into pharmaceutical compositions comprising a carrier suitable for the desired delivery method. Suitable carriers include any material that when combined with the therapeutic composition retains the anti-tumor function of the therapeutic composition and is generally non-reactive with the patient's immune system. Examples include, but are not limited to, any of a number of standard pharmaceutical carriers such as sterile phosphate buffered saline solutions, bacteriostatic water, and the like (see, generally, Remington's Pharmaceutical Sciences 16^(th) Edition, A. Osal., Ed., 1980).

Therapeutic formulations can be solubilized and administered via any route capable of delivering the therapeutic composition to the tumor site. Potentially effective routes of administration include, but are not limited to, intravenous, parenteral, intraperitoneal, intramuscular, intratumor, intradermal, intraorgan, orthotopic, and the like. A preferred formulation for intravenous injection comprises the therapeutic composition in a solution of preserved bacteriostatic water, sterile unpreserved water, and/or diluted in polyvinylchloride or polyethylene bags containing 0.9% sterile Sodium Chloride for Injection, USP. Therapeutic protein preparations can be lyophilized and stored as sterile powders, preferably under vacuum, and then reconstituted in bacteriostatic water (containing for example, benzyl alcohol preservative) or in sterile water prior to injection.

Dosages and administration protocols for the treatment of cancers using the foregoing methods will vary with the method and the target cancer, and will generally depend on a number of other factors appreciated in the art.

XIII.) Kits

For use in the diagnostic and therapeutic applications described herein, kits are also within the scope of the invention. Such kits can comprise a carrier, package or container that is compartmentalized to receive one or more containers such as vials, tubes, and the like, each of the container(s) comprising one of the separate elements to be used in the method. For example, the container(s) can comprise a probe that is or can be detectably labeled. Such probe can be an antibody or polynucleotide specific for a FIG. 2–related protein or a FIG. 2 gene or message, respectively. Where the method utilizes nucleic acid hybridization to detect the target nucleic acid, the kit can also have containers containing nucleotide(s) for amplification of the target nucleic acid sequence and/or a container comprising a reporter-means, such as a biotin-binding protein, such as avidin or streptavidin, bound to a reporter molecule, such as an enzymatic, florescent, or radioisotope label. The kit can include all or part of the amino acid sequences in FIG. 2 or FIG. 3 or analogs thereof, or a nucleic acid molecules that encodes such amino acid sequences.

The kit of the invention will typically comprise the container described above and one or more other containers comprising materials desirable from a commercial and user standpoint, including buffers, diluents, filters, needles, syringes; carrier, package, container, vial and/or tube labels listing contents and/or instructions for use, and package inserts with instructions for use.

A label can be present on the container to indicate that the composition is used for a specific therapy or non-therapeutic application, and can also indicate directions for either in vivo or in vitro use, such as those described above. Directions and or other information can also be included on an insert which is included with the kit.

EXAMPLES

Various aspects of the invention are further described and illustrated by way of the several examples that follow, none of which are intended to limit the scope of the invention.

Example 1 SSH-Generated Isolation of a cDNA Fragment of the Target of the Invention Gene

The suppression subtractive hybridization (SSH) cDNA fragments shown in FIG. 1 were derived from many different subtractions utilizing LAPC xenografts in differing states of androgen dependence and/or castration as well as using cancer patient derived tissues. The cancer patient tissue SSHs utilized prostate, bladder, and kidney with tumors representing all stages and grades of the diseases. Information for additional sequences disclosed in FIG. 2 and FIG. 3 were derived from other clones and the use of various sequence databases.

Materials and Methods

LAPC Xenografts and Human Tissues:

LAPC xenografts were obtained from Dr. Charles Sawyers (UCLA) and generated as described (Klein et al., 1997, Nature Med. 3: 402-408; Craft et al., 1999, Cancer Res. 59: 5030-5036). Androgen dependent and independent LAPC xenografts were grown in male SCID mice and were passaged as small tissue chunks in recipient males. LAPC xenografts were derived from LAPC tumors. To generate the androgen independent (AI) xenografts, male mice bearing androgen dependent (AD) tumors were castrated and maintained for 2-3 months. After the tumors re-grew, the tumors were harvested and passaged in castrated males or in female SCID mice. Tissues from prostate, bladder, kidney, colon, lung, pancreas, ovary and breast cancer patients as well as the corresponding normal tissues were stored frozen at −70 C prior to RNA isolation.

RNA Isolation:

Tumor tissue and cell lines were homogenized in Trizol reagent (Life Technologies, Gibco BRL) using 10 ml/g tissue or 10 ml/10⁸ cells to isolate total RNA. Poly A RNA was purified from total RNA using Qiagen's Oligotex mRNA Mini and Midi kits. Total and mRNA were quantified by spectrophotometric analysis (O.D. 260/280 nm) and analyzed by gel electrophoresis.

Oligonucleotides:

The following HPLC purified oligonucleotides were used.

DPNCDN (cDNA synthesis primer): (SEQ ID NO: 178) 5′TTTTGATCAAGCTT₃₀3′ Adaptor 1: (SEQ ID NO: 179) 5′CTAATACGACTCACTATAGGGCTCGAGCGGCCGCCCGGGCAG3′ (SEQ ID NO: 180) 3′GGCCCGTCCTAG5′ Adaptor 2: (SEQ ID NO: 181) 5′GTAATACGACTCACTATAGGGCAGCGTGGTCGCGGCCGAG3′ (SEQ ID NO: 182) 3′CGGCTCCTAG5′ PCR primer 1: (SEQ ID NO: 183) 5′CTAATACGACTCACTATAGGGC3′ Nested primer (NP)1: (SEQ ID NO: 184) 5′TCGAGCGGCCGCCCGGGCAGGA3′ Nested primer (NP)2: (SEQ ID NO: 185) 5′AGCGTGGTCGCGGCCGAGGA3′ Suppression Subtractive Hybridization:

Suppression Subtractive Hybridization (SSH) was used to identify cDNAs corresponding to genes that are differentially expressed in cancer. The SSH reaction utilized cDNA from the prostate cancer xenografts, LAPC-4 AD, LAPC-4 AI, LAPC-9 AD, and LAPC-9AI as well as from prostate, bladder, and kidney cancer patients. Specifically, to isolate genes that are involved in the progression of androgen dependent (AD) prostate cancer to androgen independent (AI) cancer, experiments were conducted with the LAPC-9 AD and LAPC-4 AD xenograft in male SCID mice. Mice that harbored these xenografts were castrated when the tumors reached a size of 1 cm in diameter. The tumors regressed in size and temporarily stopped producing the androgen dependent protein PSA. Seven to fourteen days post-castration, PSA levels were detectable again in the blood of the mice. Eventually the tumors develop an AI phenotype and start growing again in the castrated males. Tumors were harvested at different time points after castration to identify genes that are turned on or off during the transition to androgen independence.

The cDNAs derived from LAPC-4 AD and LAPC-9 AD tumors (post-castration) were used as the source of the “tester” cDNAs, while the cDNAs from LAPC4-AD and LAPC-9 AD tumors (grown in intact male mouse) were used as the source of the “driver” cDNAs respectively. Some SSHs also used any combination of the LAPC-4 AD, LAPC-4 AI, LAPC-9AD, and LAPC9-AI xenografts as “tester” or “driver”. In addition, cDNAs derived from patient tumors of prostate, bladder and kidney cancer were used as “tester” while cDNAs derived from normal prostate, bladder, and kidney were used as “driver” respectively. Double stranded cDNAs corresponding to tester and driver cDNAs were synthesized from 2 μg of poly(A)⁺ RNA isolated from the relevant xenograft tissue, as described above, using CLONTECH's PCR-Select cDNA Subtraction Kit and 1 ng of oligonucleotide DPNCDN as primer. First- and second-strand synthesis were carried out as described in the Kit's user manual protocol (CLONTECH Protocol No. PT1117-1, Catalog No. K1804-1). The resulting cDNA was digested with Dpn II for 3 hrs at 37° C. Digested cDNA was extracted with phenol/chloroform (1:1) and ethanol precipitated.

Tester cDNA was generated by diluting 1 μl of Dpn II digested cDNA from the relevant xenograft source (see above) (400 ng) in 5 μl of water. The diluted cDNA (2 μl, 160 ng) was then ligated to 2 μl of Adaptor 1 and Adaptor 2 (10 μM), in separate ligation reactions, in a total volume of 10 μl at 16° C. overnight, using 400 u of T4 DNA ligase (CLONTECH). Ligation was terminated with 1 μl of 0.2 M EDTA and heating at 72° C. for 5 min.

The first hybridization was performed by adding 1.5 μl (600 ng) of driver cDNA to each of two tubes containing 1.5 μl (20 ng) Adaptor 1- and Adaptor 2-ligated tester cDNA. In a final volume of 4 μl, the samples were overlaid with mineral oil, denatured in an MJ Research thermal cycler at 98° C. for 1.5 minutes, and then were allowed to hybridize for 8 hrs at 68° C. The two hybridizations were then mixed together with an additional 1 μl of fresh denatured driver cDNA and were allowed to hybridize overnight at 68° C. The second hybridization was then diluted in 200 μl of 20 mM Hepes, pH 8.3, 50 mM NaCl, 0.2 mM EDTA, heated at 70° C. for 7 min. and stored at −20° C.

PCR Amplification, Cloning and Sequencing of Gene Fragments Generated from SSH:

To amplify gene fragments resulting from SSH reactions, two PCR amplifications were performed. In the primary PCR reaction 1 μl of the diluted final hybridization mix was added to 1 μl of PCR primer 1 (10 μM), 0.5 μl dNTP mix (10 μM), 2.5 μl 10× reaction buffer (CLONTECH) and 0.5 μl 50× Advantage cDNA polymerase Mix (CLONTECH) in a final volume of 25 μl. PCR 1 was conducted using the following conditions: 75° C. for 5 min., 94° C. for 25 sec., then 27 cycles of 94° C. for 10 sec, 66° C. for 30 sec, 72° C. for 1.5 min. Five separate primary PCR reactions were performed for each experiment. The products were pooled and diluted 1:10 with water. For the secondary PCR reaction, 1 μl from the pooled and diluted primary PCR reaction was added to the same reaction mix as used for PCR 1, except that primers NP1 and NP2 (10 μM) were used instead of PCR primer 1. PCR 2 was performed using 10-12 cycles of 94° C. for 10 sec, 68° C. for 30 sec, and 72° C. for 1.5 minutes. The PCR products were analyzed using 2% agarose gel electrophoresis.

The PCR products were inserted into pCR2.1 using the T/A vector cloning kit (Invitrogen). Transformed E. coli were subjected to blue/white and ampicillin selection. White colonies were picked and arrayed into 96 well plates and were grown in liquid culture overnight. To identify inserts, PCR amplification was performed on 1 μl of bacterial culture using the conditions of PCR1 and NP1 and NP2 as primers. PCR products were analyzed using 2% agarose gel electrophoresis.

Bacterial clones were stored in 20% glycerol in a 96 well format. Plasmid DNA was prepared, sequenced, and subjected to nucleic acid homology searches of the GenBank, dBest, and NCI-CGAP databases.

A full-length cDNA clone can be identified by assembling EST fragments homologous to the SSH fragment into a large contiguous sequence with an ORF and amplifying the ORF by PCR using xenograft, prostate, bladder, kidney, prostate cancer, bladder cancer, or kidney cancer first strand cDNA.

Example 2 Full Length Cloning of a Target of the Invention

Full length cDNA clones were isolated by a variety of methods known in the art. For example, cDNA phage libraries were constructed from normal and cancer tissues using methods based on those set forth in Current Protocols in Molecular Biology, Ed Ausubel et al., page 5.01, to 5.11.1, through supplement 52, Wiley and Sons; Molecular Cloning, 2^(nd) Edition, Sambrook et al. Eds, pp. 8.2 to 8.45, 1989, Cold Spring Harbor Press) and full length cDNA clone isolated using probes derived from SSH clones and methods based on (Ausubel et al., supra, pp. 6.0.1 to 6.5.2; Sambrook et al. Eds, supra, 1989, pp. 8.46 to 8.86). In addition, some full length cDNAs were cloned using PCR with primers derived from the extreme ends of ORFs identified in ESTs assembled into contigs. The PCR product is subsequently cloned into pCR2.1 cloning vector (Invitrogen, Carlsbad, Calif.). Sequences of the cloned genes are listed in FIG. 2.

Example 3 Chromosomal Mapping

Chromosomal localization can implicate genes in disease pathogenesis. Several chromosome mapping approaches are available including fluorescent in situ hybridization (FISH), human/hamster radiation hybrid (RH) panels (Walter et al., 1994; Nature Genetics 7:22; Research Genetics, Huntsville Al), human-rodent somatic cell hybrid panels such as is available from the Coriell Institute (Camden, N.J.), and genomic viewers utilizing BLAST homologies to sequenced and mapped genomic clones (NCBI, Bethesda, Md.).

Using FIG. 2 gene sequences and the NCBI BLAST tool, placed the genes of FIG. 2 to the chromosome locations listed in Table XXII.

Accordingly, as the human genes set forth in FIG. 2 map to the designated chromosomes, polynucleotides encoding different regions of the of FIG. 2 protein can be used to characterize cytogenetic abnormalities on a respective chromosome For example, when chromosomal abnormalities in a chromosome listed in Table XXII have been identified as frequent cytogenetic abnormalities in different cancers (see, e.g., Lai et al., 2000, Clin. Cancer Res. 6(8):3172-6; Oya and Schulz, 2000, Br. J. Cancer 83(5):626-31; Svaren et al., Sep. 12, 2000, J. Biol. Chem.); polynucleotides encoding specific regions of the of a FIG. 2 protein provide new tools that are used to delineate, with greater precision than previously possible, the specific nature of the cytogenetic abnormalities in this region of the respective chromosome that contribute to the malignant phenotype. In this context, these polynucleotides satisfy a need in the art for expanding the sensitivity of chromosomal screening in order to identify more subtle and less common chromosomal abnormalities (see, e.g., Evans et al., 1994, Am. J. Obstet. Gynecol. 171(4):1055-1057).

Example 4 Expression Analysis of a Gene of the Invention in Normal Tissues and Patient Specimens

Expression analysis by RT-PCR and Northern analysis demonstrated that normal tissue expression of a gene of FIG. 2 is restricted predominantly to the tissues set forth in Table I.

Therapeutic applications for a gene of FIG. 2 include use as a small molecule therapy and/or a vaccine (T cell or antibody) target. Diagnostic applications for a gene of FIG. 2 include use as a diagnostic marker for local and/or metastasized disease. The restricted expression of a gene of FIG. 2 in normal tissues makes it useful as a tumor target for diagnosis and therapy. Expression analysis of a gene of FIG. 2 provides information useful for predicting susceptibility to advanced stage disease, rate of progression, and/or tumor aggressiveness. Expression status of a gene of FIG. 2 in patient samples, tissue arrays and/or cell lines may be analyzed by: (i) immunohistochemical analysis; (ii) in situ hybridization; (iii) RT-PCR analysis on laser capture micro-dissected samples; (iv) Western blot analysis; and (v) Northern analysis.

RT-PCR analysis and Northern blotting were used to evaluate gene expression in a selection of normal and cancerous urological tissues. The results are summarized in FIGS. 15-74.

RT-PCR Expression Analysis:

First strand cDNAs can be generated from 1 μg of mRNA with oligo (dT)12-18 priming using the Gibco-BRL Superscript Preamplification system. The manufacturer's protocol was used which included an incubation for 50 min at 42° C. with reverse transcriptase followed by RNAse H treatment at 37° C. for 20 min. After completing the reaction, the volume can be increased to 200 μl with water prior to normalization. First strand cDNAs from 16 different normal human tissues can be obtained from Clontech.

Normalization of the first strand cDNAs from multiple tissues was performed by using the primers 5′atatcgccgcgctcgtcgtcgacaa3′ (SEQ ID NO: 186) and 5′agccacacgcagctcattgtagaagg 3′ (SEQ ID NO: 187) to amplify β-actin. First strand cDNA (5 μl) were amplified in a total volume of 50 μl containing 0.4 μM primers, 0.2 μM each dNTPs, 1×PCR buffer (Clontech, 10 mM Tris-HCL, 1.5 mM MgCl₂, 50 mM KCl, pH8.3) and 1× Klentaq DNA polymerase (Clontech). Five μl of the PCR reaction can be removed at 18, 20, and 22 cycles and used for agarose gel electrophoresis. PCR was performed using an MJ Research thermal cycler under the following conditions: Initial denaturation can be at 94° C. for 15 sec, followed by a 18, 20, and 22 cycles of 94° C. for 15, 65° C. for 2 min, 72° C. for 5 sec. A final extension at 72° C. was carried out for 2 min. After agarose gel electrophoresis, the band intensities of the 283 b.p. β-actin bands from multiple tissues were compared by visual inspection. Dilution factors for the first strand cDNAs were calculated to result in equal β-actin band intensities in all tissues after 22 cycles of PCR. Three rounds of normalization can be required to achieve equal band intensities in all tissues after 22 cycles of PCR.

To determine expression levels of the gene, 5 μl of normalized first strand cDNA are analyzed by PCR using 26, and 30 cycles of amplification. Semi-quantitative expression analysis can be achieved by comparing the PCR products at cycle numbers that give light band intensities. RT-PCR expression analysis is performed on first strand cDNAs generated using pools of tissues from multiple samples. The cDNA normalization was demonstrated in every experiment using beta-actin PCR.

Northern Blot Expression Analysis:

Expression of mRNA in normal and cancerous human tissues was analyzed by northern blotting. Expression in normal tissues was analyzed using two multiple tissue blots (Clontech; Palo Alto, Calif.), comprising a total of 16 different normal human tissues, using labeled SSH fragment as a probe. To further analyze expression in prostate cancer tissues, northern blotting was performed on RNA derived from the LAPC xenografts and/or prostate cancer patient samples. In addition, expression in other cancers was studied using patient samples and/or various cancer cell lines.

FIG. 15 shows expression of 74P3B3 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), two prostate metastasis to lymph node (LN) harvested from two different patients, prostate cancer pool, bladder cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 74P3B3, was performed at 26 and 30 cycles of amplification. Results show strong expression of 74P3B3 in the two prostate metastasis to LN specimens and in prostate cancer pool. Expression was also detected in bladder cancer pool, cancer metastasis pool, and vital pool 2 but not in the vital pool 1.

FIG. 16 shows expression of 74P3B3 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 74P3B3 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 7 kb 74P3B3 transcript in prostate but not in the other normal tissues tested. Expression was also detected in LAPC-4AD and LAPC-4AI but not in LAPC-9AD and LAPC-9AI.

FIG. 17 shows expression of 74P3B3 in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), pool of 3 prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 mg of total RNA/lane was probed with 74P3B3 SSH sequence. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 74P3B3 in normal prostate and in patient prostate cancer specimens.

FIG. 18 shows expression of 74P3B3 in patient cancer specimens. Expression of 74P3B3 was assayed in a panel of human cancers (T) and their respective matched normal tissues (N) on RNA dot blots. Upregulated expression of 74P3B3 in tumors compared to normal tissues was observed in prostate, kidney, breast and colon tumors. The expression detected in normal adjacent tissues (isolated from diseased tissues) but not in normal tissues (isolated from healthy donors) may indicate that these tissues are not fully normal and that 74P3B3 may be expressed in early stage tumors.

FIG. 19 shows expression of 83P4B8 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 83P4B8, was performed at 30 cycles of amplification. Results show strong expression of 83P4B8 in all cancer pools tested. Very low expression was detected in the vital pools.

FIG. 20 shows expression of 83P4B8 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 83P4B8 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of two approximately 4.4 kb 83P4B8 transcripts in testis and to lower level in thymus but not in the other normal tissues tested. Expression was also detected in all 4 LAPC prostate cancer xenografts.

FIG. 21 shows expression of 83P4B8 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three prostate cancers (PC), bladder cancers (BC), kidney cancers (KC), colon cancers (CC), lung cancers (LC), ovary cancers (OC), cancer metastasis (Met), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr) normal ovary (NO) and normal pancreas (NPa). Northern blot with 10 mg of total RNA/lane was probed with 83P4B8 sequence. Size standards in kilobases (kb) are indicated on the side. Results show expression of 83P4B8 in the bladder cancers and ovary cancers. Expression of 83P4B8 was also detected in prostate cancers, kidney cancers, colon cancers, lung cancers, cancer metastasis and pancreas cancer but not in the normal tissues tested.

FIG. 22 shows expression of 83P4B8 in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 mg of total RNA/lane was probed with 83P4B8 SSH sequence. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 83P4B8 in the patient prostate cancer specimens.

FIG. 23 shows expression of 83P4B8 in colon cancer patient specimens. RNA was extracted from colon cancer cell lines (CL), normal colon (N), colon cancer patient tumors (T) and their normal adjacent tissues (Nat). Northern blots with 10 μg of total RNA were probed with the 83P4B8 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 83P4B8 in the colon tumor tissues and in all three colon cancer cell lines tested, but not in the normal tissues.

FIG. 24 shows expression of 109P1D4 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 109P1D4, was performed at 30 cycles of amplification. Results show strong expression of 109P1D4 in all cancer pools tested. Very low expression was detected in the vital pools

FIG. 25 shows expression of 109P1D4 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 109P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 10 kb 109P1D4 transcript in ovary. Weak expression was also detected in placenta and brain, but not in the other normal tissues tested.

FIG. 26 shows expression of 109P1D4 in human cancer cell lines. RNA was extracted from a number of human prostate and bone cancer cell lines. Northern blots with 10 μg of total RNA/lane were probed with the 109P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of 109P1D4 in LAPC-9AD, LAPC-9AI, LNCaP prostate cancer cell lines, and in the bone cancer cell lines, SK-ES-1 and RD-ES.

FIG. 27 shows expression of 109P1D4 in patient cancer specimens. Expression of 109P1D4 was assayed in a panel of human cancers (T) and their respective matched normal tissues (N) on RNA dot blots. Upregulated expression of 109P1D4 in tumors compared to normal tissues was observed in uterus, lung and stomach. The expression detected in normal adjacent tissues (isolated from diseased tissues) but not in normal tissues (isolated from healthy donors) may indicate that these tissues are not fully normal and that 109P1D4 may be expressed in early stage tumors.

FIG. 28 shows expression of 151P1C7A by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 151P1C7A, was performed at 26 and 30 cycles of amplification. Results show strong expression of 151P1C7A in bladder, lung, and metastasis cancer pools tested. Expression was also detected in xenograft, prostate, kidney and colon cancer pools but not in the vital pools.

FIG. 29 shows expression of 151P1C7A in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 151P1C7A SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2 kb 151P1C7A transcript in placenta but not in the other normal tissues tested.

FIG. 30 shows expression of 151P1C7A in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 151P1C7A SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 151P1C7A in patient bladder cancer tissues, and in all bladder cancer cell lines tested, but not in normal bladder.

FIG. 31 shows expression of 151P1C7A in prostate cancer patient specimens. RNA was extracted from normal prostate (NP), prostate cancer patient tumors (T) and their normal adjacent tissues (N). Northern blot with 10 mg of total RNA/lane was probed with 151P1C7A SSH sequence. Size standards in kilobases (kb) are indicated on the side. Results show expression of 151P1C7A in the patient prostate cancer specimens.

FIG. 32 shows expression of 151P4E11 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 151P4E11, was performed at 26 and 30 cycles of amplification. Results show strong expression of 151P4E11 in all cancer pools tested. Expression was detected in vital pool 2 but not in vital pool 1.

FIG. 33 shows expression of 151P4E11 in normal tissues. Two multiple tissue northern blots (A and B; Clontech) both with 2 μg of mRNA/lane, and a LAPC xenograft blot with 10 μg of total RNA/lane (C) were probed with the 151P4E11 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 1.2 kb 151P4E11 transcript in prostate, testis, colon and small intestine. Expression was also detected in all the LAPC prostate cancer xenografts LAPC-4AD, LAPC-4AI, and LAPC-9AI, but not in LAPC-9AD.

FIG. 34 shows expression of 154P2A8 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 154P2A8, was performed at 26 and 30 cycles of amplification. Results show strong expression of 154P2A8 in bladder cancer pool and lung cancer pool. Expression was also detected in prostate cancer pool, kidney cancer pool, colon cancer pool, and cancer metastasis pool but not in vital pool 1 and vital pool 2.

FIG. 35 shows expression of 156P1D4 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 156P1D4, was performed at 26 and 30 cycles of amplification. Results show strong expression of 156P1D4 in kidney cancer pool and vital pool 1. Expression was also detected in xenograft pool, prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and vital pool 2.

FIG. 36 shows expression of 156P1D4 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 156P1D4 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2 kb 156P1D4 transcript in kidney and prostate but not in the other normal tissues tested.

FIG. 37 shows expression of 156P1D4 in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N). Northern blots with 10 μg of total RNA were probed with the 156P1D4 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 156P1D4 in all kidney tumor tissues tested. The expression of 156P1D4 detected in tumor tissues is stronger than in normal tissues.

FIG. 38 shows expression of 156P5C12 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 156P5C12, was performed at 26 and 30 cycles of amplification. Results show strong expression of 156P5C12 in kidney cancer pool and vital pool 1. Expression was also detected in xenograft pool, prostate cancer pool, bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and vital pool 2.

FIG. 39 shows expression of 156P5C12 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 156P5C12 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 1.4 kb 156P5C12 transcript in kidney but not in the other normal tissues tested.

FIG. 40 shows expression of 156P5C12 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, SW839), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT). Northern blots with 10 μg of total RNA were probed with the 156P5C12 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 156P5C12 in normal tissues, and in some but not all kidney tumor tissues. Expression was absent in the kidney cancer cell lines tested.

FIG. 41 shows expression of 159P2B5 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), and bladder cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 159P2B5, was performed at 26 and 30 cycles of amplification. Results show expression of 159P2B5 in bladder cancer pool tested but not in the vital pools.

FIG. 42 shows expression of 159P2B5 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 159P2B5 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show very weak expression of an approximately 4.5 kb159P2B5 transcript in spleen, kidney and small intestine.

FIG. 43 shows expression of 159P2B5 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (NB), and bladder cancer patient tumors (T) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 159P2B5 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 159P2B5 in patient bladder cancer tissues, and in the SCaBER bladder cancer cell line, but not in normal bladder, nor in the other cancer cell lines tested.

FIG. 44 shows expression of 161P2B7A by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate metastasis to lymph node (LN), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 161P2B7A, was performed at 26 and 30 cycles of amplification. Results show strong expression of 161P2B7A in lung cancer pool and pancreas cancer pool. Expression was also detected in prostate metastasis to LN, prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, ovary cancer pool, breast cancer pool, and cancer metastasis pool. Very low expression was observed in vital pool 2 but not in vital pool 1.

FIG. 45 shows expression of 161P2B7A in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 161P2B7A SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show very low expression of 161P2B7A in testis but not in the other normal tissues tested.

FIG. 46 shows expression of 161P2B7A in Multiple Normal Tissues. An mRNA dot blot containing 76 different samples from human tissues was analyzed using a 161P2B7A SSH probe. Expression was not detected in any of the 76 normal tissues tested. The positive genomic DNA control showed very strong signal confirming the validity of the experiment.

FIG. 47 shows expression of 161P2B7A in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 161P2B7A SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of two 161P2B7A transcripts, approximately 1.2 and 7 kb, in kidney cancer specimens but not in normal kidney.

FIG. 48 shows expression of 161P2B7A in lung cancer patient specimens. RNA was extracted from lung cancer cell lines (CL), normal lung, lung tumors (T), and their normal adjacent tissues (NAT) isolated from lung cancer patients. Northern blot with 10 mg of total RNA/lane was probed with the 161P2B7A fragment. Size standards in kilobases (kb) are indicated on the side. The results show expression of 161P2B7A in the lung tumors, but not in normal lung tissues. Expression was also detected in the lung cancer cell lines CALU-1, A427 and NCI-146 but not in the small cell lung cancer cell line NCI-H82.

FIG. 49 shows expression of 161P2B7A in pancreas and ovary cancer patient specimens. RNA was extracted from normal pancreas (NPa), pancreas cancer (PC), normal ovary (NO), and ovary cancer patient specimen (OC). Northern blot with 10 mg of total RNA/lane was probed with the 161P2B7A fragment. Size standards in kilobases (kb) are indicated on the side. The results show expression of 161P2B7A in the pancreas and ovary cancer patient specimens, but not in the normal tissues.

FIG. 50 shows expression of 179P3G7 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), bladder cancer pool, kidney cancer pool, lung cancer pool, breast cancer pool, cancer metastasis pool, pancreas cancer pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 179P3G7, was performed at 26 and 30 cycles of amplification. Results show strong expression of 179P3G7 in kidney cancer pool and breast cancer pool. Expression was also detected in bladder cancer pool, lung cancer pool, cancer metastasis pool, pancreas cancer pool and prostate metastasis to LN, and vital pool 1, but not in vital pool 2.

FIG. 51 shows expression of 179P3G7 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 179P3G7 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of 179P3G7 strongly in skeletal muscle, and weakly in kidney, liver and heart but not in the other normal tissues tested.

FIG. 52 shows expression of 179P3G7 in kidney cancer patient specimens. RNA was extracted from normal kidney (Nk), kidney cancer patient tumors (T) and their normal adjacent tissues (N) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 179P3G7 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 179P3G7 in kidney cancer specimens. Expression of 179P3G7 is stronger in kidney tumors compared to normal kidney tissues.

FIG. 53 shows expression of 184P3C10B by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, and cancer metastasis pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 184P3C10B, was performed at 26 and 30 cycles of amplification. Results show expression of 184P3C10B in xenograft pool, prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, and cancer metastasis pool. Expression was also detected in vital pool 2 but at a much lower level in vital pool 1.

FIG. 54 shows expression of 184P3C10B in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 184P3C10B SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of approximately 2.4 and 5 kb 184P3C10B transcripts in placenta and to lower level in colon and small intestine, but not in the other normal tissues tested.

FIG. 55 shows expression of 184P3C10B in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 184P3C10B SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 184P3C10B in patient bladder cancer tissues, and in the bladder cancer cell line SCaBER, but not in normal bladder nor in the other bladder cancer cell lines tested.

FIG. 56 shows expression of 184P3G10 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), LAPC prostate cancer xenograft pool (LAPC-4AD, LAPC-4AI, LAPC-9AD and LAPC-9AI), bladder cancer pool, kidney cancer pool, colon cancer pool, and lung cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 184P3G10, was performed at 26 and 30 cycles of amplification. Results show strong expression of 184P3G10 in bladder cancer pool, kidney cancer pool, and colon cancer pool. Expression was also detected in xenograft pool, lung cancer pool, vital pool 2 but not in vital pool 1.

FIG. 57 shows expression of 184P3G10 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 184P3G10 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of two approximately 4.4 kb 184P3G10 transcripts in colon and small intestine, but not in the other normal tissues tested.

FIG. 58 shows expression of 184P3G10 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three bladder cancers, colon cancers, lung cancers, breast cancers, ovary cancers, cancer metastasis, as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK). Northern blot with 10 mg of total RNA/lane was probed with 184P3G10 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 184P3G10 in the bladder cancers, colon cancers and ovary cancers. Expression of 184P3G10 was also detected in lung cancers, breast cancers, and cancer metastasis but not in the normal tissues tested.

FIG. 59 shows expression of 184P3G10 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (N), bladder cancer patient tumors (T) and their normal adjacent tissue (Nat) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 184P3G10 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 184P3G10 in patient bladder cancer tissues, but not in normal bladder nor in the bladder cancer cell lines tested.

FIG. 60 shows expression of 185P2C9 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate metastasis to lymph node (LN), prostate cancer pool, bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 185P2C9, was performed at 30 cycles of amplification. Results show strong expression of 185P2C9 in bladder cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool and pancreas cancer pool. Expression was also detected in prostate metastasis to LN, prostate cancer pool, kidney cancer pool, breast cancer pool, cancer metastasis pool, vital pool 2 but not in vital pool 1.

FIG. 61 shows expression of 185P2C9 in normal tissues. Two multiple tissue northern blots (Clontech), both with 2 μg of mRNA/lane, were probed with the 185P2C9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of and approximately 8.5 kb 185P2C9 transcript in testis and brain, but not in the other normal tissues tested.

FIG. 62 shows expression of 185P2C9 in bladder cancer patient specimens. RNA was extracted from bladder cancer cell lines (CL; UM-UC-3, J82, SCaBER), normal bladder (Nb), bladder cancer patient tumors (T) and their normal adjacent tissue (N) isolated from bladder cancer patients. Northern blots with 10 μg of total RNA were probed with the 185P2C9 SSH sequence. Size standards in kilobases are indicated on the side. Results show expression of 185P2C9 in bladder cancer patient tissues, and in the bladder cancer cell lines tested. Expression of 185P2C9 is significantly stronger in bladder tumor tissues compared to normal tissues.

FIG. 63 shows expression of 185P2C9 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, Caki-1), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 185P2C9 SSH fragment. Size standards in kilobases are indicated on the side. Results show expression of 185P2C9 in kidney cancer specimens and kidney cancer cell lines, but not in normal kidney.

FIG. 64 shows expression of 186P1H9 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), bladder cancer pool, kidney cancer pool, colon cancer pool, lung cancer pool, ovary cancer pool, cancer metastasis pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 186P1H9, was performed at 26 and 30 cycles of amplification. Results show strong expression of 186P1H9 in kidney cancer pool, colon cancer pool, ovary cancer pool, cancer metastasis pool, and pancreas cancer pool. Expression was also detected in bladder cancer pool, lung cancer pool, and vital pool 2 but not in vital pool 1.

FIG. 65 shows expression of 186P1H9 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 186P1H9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of an approximately 2.6 kb 186P1H9 transcript in testis, spleen, pancreas and brain. Lower expression is also detected in heart, skeletal muscle, prostate, colon and small intestine.

FIG. 66 shows expression of 186P1H9 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three kidney cancers (KC), ovary cancers (OC), cancer metastasis (Met), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr), normal ovary (NO), and normal pancreas (NPa). Northern blot with 10 mg of total RNA/lane was probed with 186P1H9 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 186P1H9 in the bladder cancers, ovary cancers, cancer metastasis and pancreas cancers, but not in normal tissues. Expression of 186P1H9 is significantly stronger in patient cancer tissues compared to normal tissues.

FIG. 67 shows expression of 186P1H9 in kidney cancer patient specimens. RNA was extracted from kidney cancer cell lines (CL; 769-P, A498, Caki-1), normal kidney (N), kidney cancer patient tumors (T) and their normal adjacent tissues (NAT) isolated from kidney cancer patients. Northern blots with 10 μg of total RNA were probed with the 186P1H9 SSH fragment. Size standards in kilobases are indicated on the side. Results show strong expression of 186P1H9 in kidney cancer patient specimens, but not in normal kidney, nor in the kidney cancer cell lines.

FIG. 68 shows expression of 186P1H9 in ovarian and testicular cancer patient specimens. RNA was extracted from normal ovary (NO), ovary cancer patient specimens (P1, P2, P3), normal testis (NTe), and testis cancer patient specimens (P4, P5, P6). Northern blot with 10 mg of total RNA/lane was probed with the 186P1H9 SSH fragment. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 186P1H9 in the ovary cancer patient specimens, but not in the normal ovary. Expression was also detected in normal and in testis cancer specimens.

FIG. 69 shows expression of 187P3F2 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), kidney cancer pool, and pancreas cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 187P3F2, was performed at 26 and 30 cycles of amplification. Results show strong expression of 187P3F2 in kidney cancer pool, pancreas cancer pool and vital pool 1, but not in vital pool 2.

FIG. 70 shows expression of 187P3F2 in normal tissues. Two multiple tissue northern blots (Clontech) both with 2 μg of mRNA/lane, were probed with the 187P3F2 SSH fragment. Size standards in kilobases (kb) are indicated on the side. Results show expression of a 4.5 kb 187P3F2 transcript in kidney and brain, but not in the other tissues tested.

FIG. 71 shows expression of 187P3F2 in patient cancer specimens and normal tissues. RNA was extracted from a pool of three kidney cancers (KC), pancreas cancers (PaC), as well as from normal prostate (NP), normal bladder (NB), and normal kidney (NK), normal colon (NC), normal lung (NL), normal breast (NBr), normal ovary (NO), and normal pancreas (NPa). Northern blot with 10 mg of total RNA/lane was probed with 187P3F2 sequence. Size standards in kilobases (kb) are indicated on the side. Results show strong expression of 187P3F2 in kidney cancers, pancreas cancers, and normal kidney, but not in the other normal tissues.

FIG. 72 shows expression of 187P3F2 in pancreas cancer patient specimens. RNA was extracted from pancreas cancer cell lines (CL), normal pancreas (N), and pancreas tumor tissues (T) isolated from pancreatic cancer patients. Northern blot with 10 mg of total RNA/lane was probed with the 187P3F2 SSH fragment. Size standards in kilobases (kb) are indicated on the side. The results show strong expression of 187P3F2 in the pancreas cancer specimens, but not in normal pancreas nor in the cancer cell lines tested.

FIG. 73 shows expression of 192P2G7 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), prostate cancer pool, bladder cancer pool, kidney cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, pancreas cancer pool, and prostate metastasis to lymph node (LN). Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 186P1H9, was performed at 26 and 30 cycles of amplification. Results show strong expression of 186P1H9 in pancreas cancer pool and prostate metastasis to LN. Expression was also detected in prostate cancer pool, bladder cancer pool, kidney cancer pool, lung cancer pool, ovary cancer pool, breast cancer pool, cancer metastasis pool, vital pool 2 but not in vital pool 1.

FIG. 74 shows expression of 185P3C2 by RT-PCR. First strand cDNA was prepared from vital pool 1 (liver, lung and kidney), vital pool 2 (pancreas, colon and stomach), and bladder cancer pool. Normalization was performed by PCR using primers to actin and GAPDH. Semi-quantitative PCR, using primers to 185P3C2, was performed at 26 and 30 cycles of amplification. Results show strong expression of 185P3C2 in bladder cancer pool. Low level expression was detected in vital pool 2, but not in vital pool 1.

Example 5 Transcript Variants of Genes of the Invention

Transcript variants are variants of matured mRNA from the same gene by alternative transcription or alternative splicing. Alternative transcripts are transcripts from the same gene but start transcription at different points. Splice variants are mRNA variants spliced differently from the same transcript. In eukaryotes, when a multi-exon gene is transcribed from genomic DNA, the initial RNA is spliced to produce functional mRNA, which has only exons and is used for translation into an amino acid sequence. Accordingly, a given gene can have zero to many alternative transcripts and each transcript can have zero to many splice variants. Each transcript variant has a unique exon makeup, and can have different coding and/or non-coding (5′ or 3′ end) portions, from the original transcript. Transcript variants can code for similar or different proteins with the same or a similar function or may encode proteins with different functions, and may be expressed in the same tissue at the same time, or at different tissue, or at different times, proteins encoded by transcript variants can have similar or different cellular or extracellular localizations, i.e., be secreted.

Transcript variants are identified by a variety of art-accepted methods. For example, alternative transcripts and splice variants are identified full-length cloning experiment, or by use of full-length transcript and EST sequences. First, all human ESTs were grouped into clusters which show direct or indirect identity with each other. Second, ESTs in the same cluster were further grouped into sub-clusters and assembled into a consensus sequence. The original gene sequence is compared to the consensus sequence(s) or other full-length sequences. Each consensus sequence is a potential splice variant for that gene. Even when a variant is identified that is not a full-length clone, that portion of the variant is very useful for antigen generation and for further cloning of the full-length splice variant, using techniques known in the art.

Moreover, computer programs available in the art are used that identify transcript variants based on genomic sequences. Genomic-based transcript variant identification programs include FgenesH (A. Salamov and V. Solovyev, “Ab initio gene finding in Drosophila genomic DNA,” Genome Research. 2000 April; 10(4): 516-22). For a general discussion of splice variant identification protocols see., e.g., Southan, C., A genomic perspective on human proteases, FEBS Lett. 2001 Jun. 8; 498(2-3):214-8; de Souza, S. J., et al., Identification of human chromosome 22 transcribed sequences with ORF expressed sequence tags, Proc. Natl. Acad Sci USA. 2000 Nov. 7; 97(23): 12690-3.

To further confirm the parameters of a transcript variant, a variety of techniques available in the art are used, such as full-length cloning, proteomic validation, PCR-based validation, and 5′ RACE validation, etc. (see e.g., Proteomic Validation: Brennan, S. O., et al., Albumin banks peninsula: a new termination variant characterized by electrospray mass spectrometry, Biochem Biophys Acta. 1999 Aug. 17; 1433(1-2):321-6; Ferranti P, et al., Differential splicing of pre-messenger RNA produces multiple forms of mature caprine alpha(s1)-casein, Eur J. Biochem. 1997 Oct. 1; 249(1):1-7. For PCR-based Validation: Wellmann S, et al., Specific reverse transcription-PCR quantification of vascular endothelial growth factor (VEGF) splice variants by LightCycler technology, Clin Chem. 2001 April; 47(4):654-60; Jia, H. P., et al., Discovery of new human beta-defensins using a genomics-based approach, Gene. 2001 Jan. 24; 263(1-2):211-8. For PCR-based and 5′ RACE Validation: Brigle, K. E., et al., Organization of the murine reduced folate carrier gene and identification of variant splice forms, Biochem Biophys Acta. 1997 Aug. 7; 1353(2): 191-8).

It is known in the art that genomic regions are modulated in cancers. When the genomic region to which a gene maps is modulated in a particular cancer, the alternative transcripts or splice variants of the gene are modulated as well. Disclosed herein is a particular expression profile of the target genes related to cancer. Alternative transcripts and splice variants of these genes may also be involved in cancers in the same or different tissues, thus serving as tumor-associated markers/antigens.

Using the full-length gene and EST sequences, five transcript variants were identified for 83P4B8, seven for 109P1D4, one for 151P4E11, two for 161P2B7A, one for 179P3G7, four for 184P3G10, two for 185P2C9, four for 185P3C2, and two for 192P2G7, as displayed in FIGS. 11-14.

FIG. 11 through FIG. 14 are set forth herein on a gene-by-gene basis. The following list shows the numbering of figures and the corresponding genes. nucleotide sequence of a transcript variant. FIG. 11 displays the nucleotide sequences of transcript variants. FIG. 12 shows amino acid sequences of proteins translated from the corresponding transcript variants. FIG. 13 displays the alignment of nucleotide sequences of transcript variants. FIG. 14 displays the alignment of protein sequences from the corresponding transcript variants.

Number of Transcript Variants for Target Genes and the Numbering of Associated Figures.

Target Gene Number of Trans. Var. FIG. Number 83P4B8 5 FIG. 11b-14b 109P1D4 7 FIG. 11c-14c 151P4E11 1 FIG. 11e-14e 161P2B7A 2 FIG. 11j-14j 179P3G7 1 FIG. 11k-14k 184P3G10 4 FIG. 11m-14m 185P2C9 2 FIG. 11n-14n 185P3C2 4 FIG. 11o-14o 192P2G7 2 FIG. 11r-14r

Example 6 Production of Recombinant Targets of the Invention in Prokaryotic Systems

To express a recombinant gene of FIG. 2 in prokaryotic cells, full or partial length gene cDNA sequences are cloned into any one of a variety of expression vectors known in the art. One or more of the following regions of genes set forth in FIG. 2, or variants or analogs thereof, are expressed in these constructs: regions that encode the entire, respective, amino acid sequence of a particular target, or any 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 or more contiguous amino acids from a protein of FIG. 2, variants, or analogs thereof.

A. In Vitro Transcription and Translation Constructs:

pCRII: To generate sense and anti-sense RNA probes for RNA in situ investigations, pCRII constructs (Invitrogen, Carlsbad Calif.) are generated encoding either all of or fragments of a cDNA. The pCRII vector has Sp6 and T7 promoters flanking the insert to drive the transcription of RNA for use as probes in RNA in situ hybridization experiments. These probes are used to analyze the cell and tissue expression of a gene at the RNA level. Transcribed RNA representing the cDNA amino acid coding region of the gene is used in in vitro translation systems such as the TnT™ Coupled Reticulolysate System (Promega, Corp., Madison, Wis.) to synthesize a protein of the invention.

B. Bacterial Constructs:

pGEX Constructs: To generate recombinant proteins of the invention in bacteria that are fused to the Glutathione S-transferase (GST) protein, all of or parts of a cDNA protein coding sequence of the invention are fused to the GST gene by cloning into pGEX-6P-1 or any other GST-fusion vector of the pGEX family (Amersham Pharmacia Biotech, Piscataway, N.J.). These constructs allow controlled expression of recombinant target of the invention protein sequences with GST fused at the amino-terminus and a six histidine epitope (6×His) at the carboxyl-terminus. The GST and 6×His tags permit purification of the recombinant fusion protein from induced bacteria with the appropriate affinity matrix and allow recognition of the fusion protein with anti-GST and anti-His antibodies. The 6×His tag is generated by adding 6 histidine codons to the cloning primer at the 3′ end, e.g., of the open reading frame (ORF). A proteolytic cleavage site, such as the PreScission™ recognition site in pGEX-6P-1, can be employed to permit cleavage of the GST tag from target of the invention-related protein. The ampicillin resistance gene and pBR322 origin permits selection and maintenance of the pGEX plasmids in E. coli.

pMAL Constructs: To generate, in bacteria, recombinant target of the invention proteins that are fused to maltose-binding protein (MBP), all of or parts of the target of the invention cDNA protein coding sequence are fused to the MBP gene by cloning into the pMAL-c2X and pMAL-p2X vectors (New England Biolabs, Beverly, Mass.). These constructs allow controlled expression of recombinant target of the invention protein sequences with MBP fused at the amino-terminus and a 6×His epitope tag at the carboxyl-terminus. The MBP and 6×His tags permit purification of the recombinant protein from induced bacteria with the appropriate affinity matrix and allow recognition of the fusion protein with anti-MBP and anti-His antibodies. The 6×His epitope tag is generated by adding 6 histidine codons to the 3′ cloning primer. A Factor Xa recognition site permits cleavage of the pMAL tag from a target of the invention. The pMAL-c2X and pMAL-p2X vectors are optimized to express the recombinant protein in the cytoplasm or periplasm respectively. Periplasm expression enhances folding of proteins with disulfide bonds.

pET Constructs: To express a target of the invention in bacterial cells, all of or parts of the target of the invention cDNA protein coding sequence are cloned into the pET family of vectors (Novagen, Madison, Wis.). These vectors allow tightly controlled expression of recombinant target of the invention protein in bacteria with and without fusion to proteins that enhance solubility, such as NusA and thioredoxin (Trx), and epitope tags, such as 6×His and S-Tag™ that aid purification and detection of the recombinant protein. For example, constructs are made utilizing pET NusA fusion system 43.1 such that regions of the target of the invention protein are expressed as amino-terminal fusions to NusA. In one embodiment, a NusA-fusion protein encompassing certain amino acids of a FIG. 2 protein with a C-terminal 6×His tag are expressed in E. coli, purified by metal chelate affinity chromatography, and used as an immunogen for generation of antibodies.

C. Yeast Constructs:

pESC Constructs: To express a target of the invention in the yeast species Saccharomyces cerevisiae for generation of recombinant protein and functional studies, all of or parts of a target of the invention cDNA protein coding sequence are cloned into the pESC family of vectors each of which contain 1 of 4 selectable markers, HIS3, TRP1, LEU2, and URA3 (Stratagene, La Jolla, Calif.). These vectors allow controlled expression from the same plasmid of up to 2 different genes or cloned sequences containing either Flag™ or Myc epitope tags in the same yeast cell. This system is useful to confirm protein-protein interactions of a target of the invention. In addition, expression in yeast yields similar post-translational modifications, such as glycosylations and phosphorylations, that are found when expressed in eukaryotic cells.

pESP Constructs: To express a target of the invention in the yeast species Saccharomyces pombe, all of or parts of a target of the invention cDNA protein coding sequence are cloned into the pESP family of vectors. These vectors allow controlled high level of expression of a target of the invention protein sequence that is fused at either the amino terminus or at the carboxyl terminus to GST which aids purification of the recombinant protein. A Flag™ epitope tag allows detection of the recombinant protein with anti-Flag™ antibody.

Example 7 Production of Recombinant Target of the Invention in Eukaryotic Systems

A. Mammalian Constructs:

To express a recombinant target of the invention in eukaryotic cells, the full or partial length target of the invention cDNA sequences can be cloned into any one of a variety of expression vectors known in the art. One or more of the following peptide regions of a protein of the invention are expressed in these constructs: any 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 or more contiguous amino acids from a protein of FIG. 2, variants, or analogs thereof. In certain embodiments a region of a specific variant of a target of the invention is expressed that encodes an amino acid at a specific position which differs from the amino acid of any other respective variant found at that position. In other embodiments, a region of a variant of the invention is expressed that lies partly or entirely within a sequence that is unique to that variant respective to other variants of that target.

The constructs can be transfected into any one of a wide variety of mammalian cells such as 293T cells. Transfected 293T cell lysates can be probed with the anti-target of the invention polyclonal serum, described herein.

pcDNA4/HisMax Constructs: To express a target of the invention in mammalian cells, a target of the invention ORF, or portions thereof, are cloned into pcDNA4/HisMax Version A (Invitrogen, Carlsbad, Calif.). Protein expression is driven from the cytomegalovirus (CMV) promoter and the SP16 translational enhancer. The recombinant protein has Xpress™ and six histidine (6×His) epitopes fused to the amino-terminus. The pcDNA4/HisMax vector also contains the bovine growth hormone (BGH) polyadenylation signal and transcription termination sequence to enhance mRNA stability along with the SV40 origin for episomal replication and simple vector rescue in cell lines expressing the large T antigen. The Zeocin resistance gene allows for selection of mammalian cells expressing the protein and the ampicillin resistance gene and ColE1 origin permits selection and maintenance of the plasmid in E. coli.

pcDNA3.1/MycHis Constructs: To express a target of the invention in mammalian cells, a target of the invention ORF, or portions thereof, with a consensus Kozak translation initiation site are cloned into pcDNA3.1/MycHis Version A (Invitrogen, Carlsbad, Calif.). Protein expression is driven from the cytomegalovirus (CMV) promoter. The recombinant proteins have the myc epitope and 6×His epitope fused to the carboxyl-terminus. The pcDNA3.1/MycHis vector also contains the bovine growth hormone (BGH) polyadenylation signal and transcription termination sequence to enhance mRNA stability, along with the SV40 origin for episomal replication and simple vector rescue in cell lines expressing the large T antigen. The Neomycin resistance gene can be used, as it allows for selection of mammalian cells expressing the protein and the ampicillin resistance gene and ColE1 origin permits selection and maintenance of the plasmid in E. coli.

pcDNA3.1/CT-GFP-TOPO Construct: To express a target of the invention in mammalian cells and to allow detection of the recombinant proteins using fluorescence, a target of the invention ORF, or portions thereof, with a consensus Kozak translation initiation site are cloned into pcDNA3.1/CT-GFP-TOPO (Invitrogen, CA). Protein expression is driven from the cytomegalovirus (CMV) promoter. The recombinant proteins have the Green Fluorescent Protein (GFP) fused to the carboxyl-terminus facilitating non-invasive, in vivo detection and cell biology studies. The pcDNA3.1CT-GFP-TOPO vector also contains the bovine growth hormone (BGH) polyadenylation signal and transcription termination sequence to enhance mRNA stability along with the SV40 origin for episomal replication and simple vector rescue in cell lines expressing the large T antigen. The Neomycin resistance gene allows for selection of mammalian cells that express the protein, and the ampicillin resistance gene and ColE1 origin permits selection and maintenance of the plasmid in E. coli. Additional constructs with an amino-terminal GFP fusion are made in pcDNA3.1/NT-GFP-TOPO spanning the entire length of a target of the invention protein.

PAPtag: A target of the invention ORF, or portions thereof, is cloned into pAPtag-5 (GenHunter Corp. Nashville, Tenn.). This construct generates an alkaline phosphatase fusion at the carboxyl-terminus of a target of the invention protein while fusing the IgGκ signal sequence to the amino-terminus. Constructs are also generated in which alkaline phosphatase with an amino-terminal IgGκ signal sequence is fused to the amino-terminus of a target of the invention protein. The resulting recombinant target of the invention proteins are optimized for secretion into the media of transfected mammalian cells and can be used to identify proteins such as ligands or receptors that interact with a target of the invention protein. Protein expression is driven from the CMV promoter and the recombinant proteins also contain myc and 6×His epitopes fused at the carboxyl-terminus that facilitates detection and purification. The Zeocin resistance gene present in the vector allows for selection of mammalian cells expressing the recombinant protein and the ampicillin resistance gene permits selection of the plasmid in E. coli.

ptag5: A target of the invention ORF, or portions thereof, is cloned into pTag-5. This vector is similar to pAPtag but without the alkaline phosphatase fusion. This construct generates a target of the invention protein with an amino-terminal IgGκ signal sequence and myc and 6×His epitope tags at the carboxyl-terminus that facilitate detection and affinity purification. The resulting recombinant target of the invention protein is optimized for secretion into the media of transfected mammalian cells, and is used as immunogen or ligand to identify proteins such as ligands or receptors that interact with target of the invention proteins. Protein expression is driven from the CMV promoter. The Zeocin resistance gene present in the vector allows for selection of mammalian cells expressing the protein, and the ampicillin resistance gene permits selection of the plasmid in E. coli.

PsecFc: A target of the invention ORF, or portions thereof, is also cloned into psecFc. The psecFc vector was assembled by cloning the human immunoglobulin G1 (IgG) Fc (hinge, CH2, CH3 regions) into pSecTag2 (Invitrogen, California). This construct generates an IgG1 Fc fusion at the carboxyl-terminus of a target of the invention protein, while fusing the IgGK signal sequence to N-terminus. Target of the invention fusions utilizing the murine IgG1 Fc region are also used. The resulting recombinant target of the invention proteins are optimized for secretion into the media of transfected mammalian cells, and can be used as immunogens or to identify proteins such as ligands or receptors that interact with a target of the invention protein. Protein expression is driven from the CMV promoter. The hygromycin resistance gene present in the vector allows for selection of mammalian cells that express the recombinant protein, and the ampicillin resistance gene permits selection of the plasmid in E. coli.

pSRα Constructs: To generate mammalian cell lines that express a target of the invention constitutively, a target of the invention ORF, or portions thereof, are cloned into pSRα constructs. Amphotropic and ecotropic retroviruses are generated by transfection of pSRα constructs into the 293T-10A1 packaging line or co-transfection of pSRα and a helper plasmid (containing deleted packaging sequences) into the 293 cells, respectively. The retrovirus is used to infect a variety of mammalian cell lines, resulting in the integration of the cloned gene, a target of the invention, into the host cell-lines. Protein expression is driven from a long terminal repeat (LTR). The Neomycin resistance gene present in the vector allows for selection of mammalian cells that express the protein, and the ampicillin resistance gene and ColE1 origin permit selection and maintenance of the plasmid in E. coli. The retroviral vectors can thereafter be used for infection and generation of various cell lines using, for example, PC3, NIH 3T3, TsuPr1, 293 or rat-1 cells.

Additional pSRα constructs are made that fuse an epitope tag such as the FLAG™ tag to the carboxyl-terminus of a target of the invention sequence to allow detection using anti-Flag antibodies. For example, the FLAG™ sequence 5′ gat tac aag gat gac gac gat aag 3′ (SEQ ID NO: 188) is added to cloning primer at the 3′ end of the ORF. Additional pSRα constructs are made to produce both amino-terminal and carboxyl-terminal GFP and myc/6×His fusion proteins of the full-length target of the invention proteins.

Additional Viral Vectors: Additional constructs are made for viral-mediated delivery and expression of a target of the invention. High virus titer leading to high level expression of a target of the invention is achieved in viral delivery systems such as adenoviral vectors and herpes amplicon vectors. A target of the invention coding sequence or fragments thereof is amplified by PCR and subcloned into the AdEasy shuttle vector (Stratagene). Recombination and virus packaging are performed according to the manufacturer's instructions to generate adenoviral vectors. Alternatively, target of the invention coding sequences or fragments thereof are cloned into the HSV-1 vector (Imgenex) to generate herpes viral vectors. The viral vectors are thereafter used for infection of various cell lines such as PC3, NIH 3T3, 293 or rat-1 cells.

Regulated Expression Systems: To control expression of a target of the invention in mammalian cells, coding sequences of a target of the invention, or portions thereof, are cloned into regulated mammalian expression systems such as the T-Rex System (Invitrogen), the GeneSwitch System (Invitrogen) and the tightly-regulated Ecdysone System (Sratagene). These systems allow the study of the temporal and concentration dependent effects of recombinant targets of the invention. These vectors are thereafter used to control expression of a target of the invention in various cell lines such as PC3, NIH 3T3, 293 or rat-1 cells.

B. Baculovirus Expression Systems

To generate recombinant target of the invention proteins in a baculovirus expression system, a target of the invention ORF, or portions thereof, are cloned into the baculovirus transfer vector pBlueBac 4.5 (Invitrogen), which provides a His-tag at the N-terminus. Specifically, pBlueBac-target of the invention nucleic acid sequence is co-transfected with helper plasmid pBac-N-Blue (Invitrogen) into SF9 (Spodoptera frugiperda) insect cells to generate recombinant baculovirus (see Invitrogen instruction manual for details). Baculovirus is then collected from cell supernatant and purified by plaque assay.

Recombinant target of the invention protein is then generated by infection of HighFive insect cells (Invitrogen) with purified baculovirus. Recombinant target of the invention protein can be detected using anti-target of the invention or anti-His-tag antibody. Target of the invention protein can be purified and used in various cell-based assays or as immunogen to generate polyclonal and monoclonal antibodies specific for a target of the invention.

Example 8 Antigenicity Profiles and Secondary Structure

FIG. 5, FIG. 6, FIG. 7, FIG. 8, and FIG. 9 depict graphically five amino acid profiles of the target of the invention amino acid sequences.

These profiles: FIG. 5, Hydrophilicity, (Hopp T. P., Woods K. R., 1981. Proc. Natl. Acad. Sci. U.S.A. 78:3824-3828); FIG. 6, Hydropathicity, (Kyte J., Doolittle R. F., 1982. J. Mol. Biol. 157:105-132); FIG. 7, Percentage Accessible Residues (Janin J., 1979 Nature 277:491-492); FIG. 8, Average Flexibility, (Bhaskaran R., and Ponnuswamy P. K., 1988. Int. J. Pept. Protein Res. 32:242-255); FIG. 9, Beta-turn (Deleage, G., Roux B. 1987 Protein Engineering 1:289-294); and optionally others available in the art, such as on the ProtScale website, were used to identify antigenic regions of the target of the invention proteins. Each of the above amino acid profiles were generated using the following ProtScale parameters for analysis: 1) A window size of 9; 2) 100% weight of the window edges compared to the window center; and, 3) amino acid profile values normalized to lie between 0 and 1.

Hydrophilicity (FIG. 5), Hydropathicity (FIG. 6) and Percentage Accessible Residues (FIG. 7) profiles were used to determine stretches of hydrophilic amino acids (i.e., values greater than 0.5 on the Hydrophilicity and Percentage Accessible Residues profile, and values less than 0.5 on the Hydropathicity profile). Such regions are likely to be exposed to the aqueous environment, be present on the surface of the protein, and thus be available for immune recognition, such as by antibodies.

Average Flexibility (FIG. 8) and Beta-turn (FIG. 9) profiles determine stretches of amino acids (i.e., values greater than 0.5 on the Beta-turn profile and the Average Flexibility profile) that are not constrained in secondary structures such as beta sheets and alpha helices. Such regions are also more likely to be exposed on the protein and thus accessible for immune recognition, such as by antibodies.

Antigenic sequences of the target of the invention proteins indicated, e.g., by the profiles set forth in FIG. 5, FIG. 6, FIG. 7, FIG. 8, and/or FIG. 9 are used to prepare immunogens, either peptides or nucleic acids that encode them, to generate therapeutic and diagnostic anti-target of the invention antibodies. The immunogen can be any 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 30, 35, 40, 45, 50 or more than 50 contiguous amino acids, or the corresponding nucleic acids that encode them, from the target of the invention variant proteins. In particular, peptide immunogens for target of the invention proteins can comprise, a peptide region of at least 5 amino acids of a protein of the invention in any whole number increment up to an entire protein that includes an amino acid position having a value greater than 0.5 in the Hydrophilicity profile of FIG. 5; a peptide region of at least 5 amino acids of a protein of the invention in any whole number increment up to the entire protein that includes an amino acid position having a value less than 0.5 in the Hydropathicity profile of FIG. 6; a peptide region of at least 5 amino acids of a protein of the invention in any whole number increment up to the entire protein that includes an amino acid position having a value greater than 0.5 in the Percent Accessible Residues profile of FIG. 7; a peptide region of at least 5 amino acids of a protein of the invention in any whole number increment up to the entire protein that includes an amino acid position having a value greater than 0.5 in the Average Flexibility profile on FIG. 8; and, a peptide region of at least 5 amino acids of a protein of the invention in any whole number increment up to the entire protein that includes an amino acid position having a value greater than 0.5 in the Beta-turn profile of FIG. 9.

All immunogens of the invention, whether peptides or nucleic acids, can be embodied in human unit dose form, or comprised by a composition that includes a pharmaceutical excipient compatible with human physiology.

The secondary structure of a protein of the invention, namely the predicted presence and location of alpha helices, extended strands, and random coils, is predicted from the primary amino acid sequence using the HNN—Hierarchical Neural Network method. The analysis provides the data set forth in FIG. 10 on a protein by protein basis.

Analysis for the presence of transmembrane domains in a protein of the invention was carried out using a variety of transmembrane prediction algorithms. The programs provide the data summarized in Table XXI on a protein by protein basis.

Example 9 Generation of Polyclonal Antibodies of the Invention

Polyclonal antibodies can be raised in a mammal, for example, by one or more injections of an immunizing agent (e.g., a protein of the invention) and, if desired, an adjuvant. Typically, the immunizing agent and/or adjuvant will be injected in the mammal by multiple subcutaneous or intraperitoneal injections. In addition to immunizing with a full length protein of the invention such as that set forth in FIG. 2, computer algorithms are employed in design of immunogens that, based on amino acid sequence analysis contain characteristics of being antigenic and available for recognition by the immune system of the immunized host (see the Example entitled “Antigenicity Profiles”). Such regions would be predicted to be hydrophilic, flexible, in beta-turn conformations, and/or be exposed on the surface of the protein (see, e.g., FIG. 5, FIG. 6, FIG. 7, FIG. 8, and FIG. 9 for amino acid profiles that indicate such regions of a protein of the invention).

For example, of FIG. 2 recombinant bacterial fusion proteins or peptides containing hydrophilic, flexible, beta-turn regions, generally found in regions between transmembrane domains and at the amino and carboxyl termini, are used as antigens to generate polyclonal antibodies in New Zealand White rabbits. Examples of such regions can be extracellular or intracellular. In addition, the amino-terminal region of a variant that is not present in a respective variant can be used as an immunogen. Antibodies to such regions are useful to distinguish one variant protein from another variant of that target. It is useful to conjugate the immunizing agent to a protein known to be immunogenic in the mammal being immunized. Examples of such immunogenic proteins include, but are not limited to, keyhole limpet hemocyanin (KLH), serum albumin, bovine thyroglobulin, and soybean trypsin inhibitor. In one embodiment, a peptide encoding amino acids from a protein of the invention is conjugated to KLH and used to immunize the rabbit. Alternatively the immunizing agent can include all or portions of the of a protein of the invention e.g. in FIG. 2, analogs or fusion proteins thereof. For example, a FIG. 2 amino acid sequence can be fused using recombinant DNA techniques to any one of a variety of fusion protein partners that are well known in the art, such as glutathione-5-transferase (GST) and HIS tagged fusion proteins. Such fusion proteins are purified from induced bacteria using the appropriate affinity matrix.

In one embodiment, a GST-fusion protein encoding amino acids of a protein of the invention is produced and purified and used as immunogen. Other recombinant bacterial fusion proteins that can be employed include maltose binding protein, LacZ, thioredoxin, NusA, or an immunoglobulin constant region (see the Example entitled “Production of Recombinant Targets of the Invention in Prokaryotic Systems” and Current Protocols In Molecular Biology, Volume 2, Unit 16, Frederick M. Ausubul et al. eds., 1995; Linsley, P. S., Brady, W., Urnes, M., Grosmaire, L., Damle, N., and Ledbetter, L. (1991) J. Exp. Med. 174, 561-566).

In addition to bacterial derived fusion proteins, mammalian expressed protein antigens are also used. These antigens are expressed from mammalian expression vectors such as the Tag5 and Fc-fusion vectors (see the Example entitled “Production of Recombinant Targets of the Invention in Eukaryotic Systems”), and retain post-translational modifications such as glycosylations found in native protein. In one embodiment, amino acids from a protein of the invention are cloned into the Tag5 mammalian secretion vector. The recombinant protein is purified by metal chelate chromatography from tissue culture supernatants of 293T cells stably expressing the recombinant vector. The purified Tag5-produced protein of the invention is then used as immunogen.

During the immunization protocol, it is useful to mix or emulsify the antigen in adjuvants that enhance the immune response of the host animal. Examples of adjuvants include, but are not limited to, complete Freund's adjuvant (CFA) and MPL-TDM adjuvant (monophosphoryl Lipid A, synthetic trehalose dicorynomycolate).

In a typical protocol, rabbits are initially immunized subcutaneously with up to 200 μg, typically 100-200 μg, of fusion protein or peptide conjugated to KLH mixed in complete Freund's adjuvant (CFA). Rabbits are then injected subcutaneously every two weeks with up to 200 μg, typically 100-200 μg, of the immunogen in incomplete Freund's adjuvant (IFA). Test bleeds are taken approximately 7-10 days following each immunization and used to monitor the titer of the antiserum by ELISA.

To test reactivity and specificity of immune serum, such as the rabbit serum derived from immunization with Tag5-produced protein of the invention, a full-length FIG. 2 cDNA is cloned into pCDNA 3.1 myc-his expression vector (Invitrogen, see the Example entitled “Production of Recombinant Targets of the Invention in Eukaryotic Systems”). After transfection of the constructs into 293T cells, cell lysates are probed with the respective anti-protein of the invention antibodies and with anti-His antibody (Santa Cruz Biotechnologies, Santa Cruz, Calif.) to determine specific reactivity of the antibodies to the respective denatured protein of the invention using the Western blot technique. Immunoprecipitation and flow cytometric analyses of 293T and other recombinant of FIG. 2–expressing cells determine recognition of native protein by the antibodies. In addition, Western blot, immunoprecipitation, fluorescent microscopy, and flow cytometric techniques using cells that endogenously express the protein of the invention are carried out to test specificity.

Anti-serum from rabbits immunized with target of the invention fusion proteins, such as GST and MBP fusion proteins, are purified by depletion of antibodies reactive to the fusion partner sequence by passage over an affinity column containing the fusion partner either alone or in the context of an irrelevant fusion protein. For example, antiserum derived from a GST- of a FIG. 2 fusion protein is first purified by passage over a column of GST protein covalently coupled to AffiGel matrix (BioRad, Hercules, Calif.). The antiserum is then affinity purified by passage over a column composed of a MBP-fusion protein also comprising those amino acids covalently coupled to Affigel matrix. The serum is then further purified by protein G affinity chromatography to isolate the IgG fraction. Sera from other His-tagged antigens and peptide immunized rabbits as well as fusion partner depleted sera are affinity purified by passage over a column matrix composed of the original protein immunogen or free peptide.

Example 10 Generation of Monoclonal Antibodies (mAbs) of the Invention

In one embodiment, therapeutic mAbs to a protein of the invention comprise those that react with epitopes of the protein that would disrupt or modulate the biological function of a protein of the invention, for example antibodies that disrupt its interaction with ligands and binding partners. Therapeutic mAbs also comprise those that specifically bind epitopes of a protein of the invention exposed on the cell surface and thus are useful in targeting mAb-toxin conjugates. Immunogens for generation of such mAbs include those designed to encode or contain an entire protein of the invention, regions of a protein of the invention predicted to be antigenic from computer analysis of the amino acid sequence (see, e.g., FIG. 5, FIG. 6, FIG. 7, FIG. 8, or FIG. 9, and the Example entitled “Antigenicity Profiles”), and regions such as extracellular domains. Immunogens include peptides, recombinant bacterial proteins, and mammalian expressed Tag 5 proteins and human and murine IgG FC fusion proteins. In addition, cells expressing high levels of a protein of the invention, such as 293T-protein of the invention or 300.19-protein of the invention murine Pre-B cells, are used to immunize mice.

To generate mAbs to a protein of the invention, mice are first immunized intraperitoneally (IP) with, typically, 10-50 μg of protein immunogen or 10⁷ protein of the invention-expressing cells mixed in complete Freund's adjuvant. Mice are then subsequently immunized IP every 2-4 weeks with, typically, 10-50 μg of protein immunogen or 10⁷ cells mixed in incomplete Freund's adjuvant. Alternatively, MPL-TDM adjuvant is used in immunizations. In addition to the above protein and cell-based immunization strategies, a DNA-based immunization protocol is employed in which a mammalian expression vector encoding a protein of the invention sequence is used to immunize mice by direct injection of the plasmid DNA. For example, amino acids from a protein of the invention are cloned into the Tag5 mammalian secretion vector and the recombinant vector is used as immunogen. In another example the same amino acids are cloned into an Fc-fusion secretion vector in which the protein of the invention sequence is fused at the amino-terminus to an IgK leader sequence and at the carboxyl-terminus to the coding sequence of the human or murine IgG Fc region. This recombinant vector is then used as immunogen. The plasmid immunization protocols are used in combination with purified proteins expressed from the same vector and with cells expressing protein of the invention.

During the immunization protocol, test bleeds are taken 7-10 days following an injection to monitor titer and specificity of the immune response. Once appropriate reactivity and specificity is obtained as determined by ELISA, Western blotting, immunoprecipitation, fluorescence microscopy, and flow cytometric analyses, fusion and hybridoma generation is then carried out with established procedures well known in the art (see, e.g., Harlow and Lane, 1988).

In one embodiment for generating monoclonal antibodies reactive with a protein of the invention, a Tag5-protein of the invention antigen is expressed and purified from stably transfected 293T cells. Balb C mice are initially immunized intraperitoneally with 25 μg of the Tag5-protein of the invention mixed in complete Freund's adjuvant. Mice are subsequently immunized every two weeks with 25 μg of the antigen mixed in incomplete Freund's adjuvant for a total of three immunizations. ELISA using the Tag5 antigen determines the titer of serum from immunized mice. Reactivity and specificity of serum to full length protein of the invention is monitored by Western blotting, immunoprecipitation and flow cytometry using 293T cells transfected with an expression vector encoding the protein of the invention cDNA (see e.g., the Example entitled “Production of Recombinant Targets of the Invention in Eukaryotic Systems”). Other recombinant protein of the invention-expressing cells or cells endogenously expressing a protein of the invention are also used. Mice showing the strongest reactivity are rested and given a final injection of Tag5 antigen in PBS and then sacrificed four days later. The spleens of the sacrificed mice are harvested and fused to SPO/2 myeloma cells using standard procedures (Harlow and Lane, 1988). Supernatants from HAT selected growth wells are screened by ELISA, Western blot, immunoprecipitation, fluorescent microscopy, and flow cytometry to identify protein of the invention-specific antibody-producing clones.

The binding affinity of a monoclonal antibody is determined using standard technologies. Affinity measurements quantify the strength of antibody to epitope binding and are used to help define which monoclonal antibodies reactive with proteins of the invention are suitable for diagnostic or therapeutic use, as appreciated by one of skill in the art. The BIAcore system (Uppsala, Sweden) is a useful method for determining binding affinity. The BIAcore system uses surface plasmon resonance (SPR, Welford K. 1991, Opt. Quant. Elect. 23:1; Morton and Myszka, 1998, Methods in Enzymology 295: 268) to monitor biomolecular interactions in real time. BIAcore analysis conveniently generates association rate constants, dissociation rate constants, equilibrium dissociation constants, and affinity constants.

Example 11 HLA Class I and Class II Binding Assays

HLA class I and class II binding assays using purified HLA molecules are performed in accordance with disclosed protocols (e.g., PCT publications WO 94/20127 and WO 94/03205; Sidney et al., Current Protocols in Immunology 18.3.1 (1998); Sidney, et al., J. Immunol. 154:247 (1995); Sette, et al., Mol. Immunol. 31:813 (1994)). Briefly, purified MHC molecules (5 to 500 nM) are incubated with various unlabeled peptide inhibitors and 1-10 nM ¹²¹I-radiolabeled probe peptides as described. Following incubation, MHC-peptide complexes are separated from free peptide by gel filtration and the fraction of peptide bound is determined. Typically, in preliminary experiments, each MHC preparation is titered in the presence of fixed amounts of radiolabeled peptides to determine the concentration of HLA molecules necessary to bind 10-20% of the total radioactivity. All subsequent inhibition and direct binding assays are performed using these HLA concentrations.

Since under these conditions [label]<[HLA] and IC₅₀≧[HLA], the measured IC₅₀ values are reasonable approximations of the true K_(D) values. Peptide inhibitors are typically tested at concentrations ranging from 120 μg/ml to 1.2 ng/ml, and are tested in two to four completely independent experiments. To allow comparison of the data obtained in different experiments, a relative binding figure is calculated for each peptide by dividing the IC₅₀ of a positive control for inhibition by the IC₅₀ for each tested peptide (typically unlabeled versions of the radiolabeled probe peptide). For database purposes, and inter-experiment comparisons, relative binding values are compiled. These values can subsequently be converted back into IC₅₀ nM values by dividing the IC₅₀ nM of the positive controls for inhibition by the relative binding of the peptide of interest. This method of data compilation is accurate and consistent for comparing peptides that have been tested on different days, or with different lots of purified MHC.

Binding assays as outlined above may be used to analyze HLA supermotif and/or HLA motif-bearing peptides.

Example 12 Identification of HLA Supermotif- and Motif-Bearing CTL Candidate Epitopes

HLA vaccine compositions of the invention can include multiple epitopes. The multiple epitopes can comprise multiple HLA supermotifs or motifs to achieve broad population coverage. This example illustrates the identification and confirmation of supermotif- and motif-bearing epitopes for the inclusion in such a vaccine composition. Calculation of population coverage is performed using the strategy described below.

Computer Searches and Algorithms for Identification of Supermotif and/or Motif-bearing Epitopes

The searches performed to identify the motif-bearing peptide sequences in the Example entitled “Antigenicity Profiles” (and, e.g., Tables V-XVIII, and Tables XXIII to XXVI) employ the protein sequence data from the protein set forth in FIGS. 2 and 3.

Computer searches for epitopes bearing HLA Class I or Class II supermotifs or motifs are performed as follows. All translated FIG. 2 protein sequences are analyzed using a text string search software program to identify potential peptide sequences containing appropriate HLA binding motifs; such programs are readily produced in accordance with information in the art in view of known motif/supermotif disclosures. Furthermore, such calculations can be made mentally.

Identified A2-, A3-, and DR-supermotif sequences are scored using polynomial algorithms to predict their capacity to bind to specific HLA-Class I or Class II molecules. These polynomial algorithms account for the impact of different amino acids at different positions, and are essentially based on the premise that the overall affinity (or ΔG) of peptide-HLA molecule interactions can be approximated as a linear polynomial function of the type: “ΔG”=a _(1i) ×a _(2i) ×a _(3i) . . . ×a _(ni) where a_(ji) is a coefficient which represents the effect of the presence of a given amino acid (j) at a given position (i) along the sequence of a peptide of n amino acids. The crucial assumption of this method is that the effects at each position are essentially independent of each other (i.e., independent binding of individual side-chains). When residue j occurs at position i in the peptide, it is assumed to contribute a constant amount j_(i) to the free energy of binding of the peptide irrespective of the sequence of the rest of the peptide.

The method of derivation of specific algorithm coefficients has been described in Gulukota et al., J. Mol. Biol. 267:1258-126, 1997; (see also Sidney et al., Human Immunol. 45:79-93, 1996; and Southwood et al., J. Immunol. 160:3363-3373, 1998). Briefly, for all i positions, anchor and non-anchor alike, the geometric mean of the average relative binding (ARB) of all peptides carrying j is calculated relative to the remainder of the group, and used as the estimate of j_(i). For Class II peptides, if multiple alignments are possible, only the highest scoring alignment is utilized, following an iterative procedure. To calculate an algorithm score of a given peptide in a test set, the ARB values corresponding to the sequence of the peptide are multiplied. If this product exceeds a chosen threshold, the peptide is predicted to bind. Appropriate thresholds are chosen as a function of the degree of stringency of prediction desired.

Selection of HLA-A2 Supertype Cross-reactive Peptides

Protein sequences from FIG. 2 proteins are scanned utilizing motif identification software, to identify 8-, 9-10- and 11-mer sequences containing the HLA-A2-supermotif main anchor specificity. Typically, these sequences are then scored using the protocol described above and the peptides corresponding to the positive-scoring sequences are synthesized and tested for their capacity to bind purified HLA-A*0201 molecules in vitro (HLA-A*0201 is considered a prototype A2 supertype molecule).

These peptides are then tested for the capacity to bind to additional A2-supertype molecules (A*0202, A*0203, A*0206, and A*6802). Peptides that bind to at least three of the five A2-supertype alleles tested are typically deemed A2-supertype cross-reactive binders. Preferred peptides bind at an affinity equal to or less than 500 nM to three or more HLA-A2 supertype molecules.

Selection of HLA-A3 Supermotif-bearing Epitopes

The FIG. 2 protein sequence(s) scanned above are also examined for the presence of peptides with the HLA-A3-supermotif primary anchors. Peptides corresponding to the HLA A3 supermotif-bearing sequences are then synthesized and tested for binding to HLA-A*0301 and HLA-A*1101 molecules, the molecules encoded by the two most prevalent A3-supertype alleles. The peptides that bind at least one of the two alleles with binding affinities of ≦500 nM, often ≦200 nM, are then tested for binding cross-reactivity to the other common A3-supertype alleles (e.g., A*3101, A*3301, and A*6801) to identify those that can bind at least three of the five HLA-A3-supertype molecules tested.

Selection of HLA-B7 Supermotif Bearing Epitopes

The FIG. 2 protein(s) scanned above are also analyzed for the presence of 8-, 9-10-, or 11-mer peptides with the HLA-B7-supermotif. Corresponding peptides are synthesized and tested for binding to HLA-B*0702, the molecule encoded by the most common B7-supertype allele (i.e., the prototype B7 supertype allele). Peptides binding B*0702 with IC₅₀ of ≦500 nM are identified using standard methods. These peptides are then tested for binding to other common B7-supertype molecules (e.g., B*3501, B*5101, B*5301, and B*5401). Peptides capable of binding to three or more of the five B7-supertype alleles tested are thereby identified.

Selection of A1 and A24 Motif-bearing Epitopes

To further increase population coverage, HLA-A1 and -A24 epitopes can also be incorporated into vaccine compositions. An analysis of the FIG. 2 proteins is performed to identify HLA-A1- and A24-motif-containing sequences.

High affinity and/or cross-reactive binding epitopes that bear other motif and/or supermotifs are identified using analogous methodology.

Example 13 Confirmation of Immunogenicity

Cross-reactive candidate CTL A2-supermotif-bearing peptides that are identified as described herein are selected to confirm in vitro immunogenicity. Conformation is performed using the following methodology:

Target Cell Lines for Cellular Screening:

The 221A2.1 cell line, produced by transferring the HLA-A2.1 gene into the HLA-A, -B, -C null mutant human B-lymphoblastoid cell line 721.221, is used as the peptide-loaded target to measure activity of HLA-A2.1-restricted CTL. This cell line is grown in RPMI-1640 medium supplemented with antibiotics, sodium pyruvate, nonessential amino acids and 10% (v/v) heat inactivated FCS. Cells that express an antigen of interest, or transfectants comprising the gene encoding the antigen of interest, can be used as target cells to confirm the ability of peptide-specific CTLs to recognize endogenous antigen.

Primary CTL Induction Cultures:

Generation of Dendritic Cells (DC): PBMCs are thawed in RPMI with 30 μg/ml DNAse, washed twice and resuspended in complete medium (RPMI-1640 plus 5% AB human serum, non-essential amino acids, sodium pyruvate, L-glutamine and penicillin/streptomycin). The monocytes are purified by plating 10×10⁶ PBMC/well in a 6-well plate. After 2 hours at 37° C., the non-adherent cells are removed by gently shaking the plates and aspirating the supernatants. The wells are washed a total of three times with 3 ml RPMI to remove most of the non-adherent and loosely adherent cells. Three ml of complete medium containing 50 ng/ml of GM-CSF and 1,000 U/ml of IL-4 are then added to each well. TNFα is added to the DCs on day 6 at 75 ng/ml and the cells are used for CTL induction cultures on day 7.

Induction of CTL with DC and Peptide: CD8+ T-cells are isolated by positive selection with Dynal immunomagnetic beads (Dynabeads® M-450) and the detacha-bead® reagent. Typically about 200-250×10⁶ PBMC are processed to obtain 24×10⁶ CD8⁺ T-cells (enough for a 48-well plate culture). Briefly, the PBMCs are thawed in RPMI with 30 μg/ml DNAse, washed once with PBS containing 1% human AB serum and resuspended in PBS/1% AB serum at a concentration of 20×10⁶ cells/ml. The magnetic beads are washed 3 times with PBS/AB serum, added to the cells (140 μl beads/20×10⁶ cells) and incubated for 1 hour at 4° C. with continuous mixing. The beads and cells are washed 4× with PBS/AB serum to remove the nonadherent cells and resuspended at 100×10⁶ cells/ml (based on the original cell number) in PBS/AB serum containing 100 μl/ml detacha-bead® reagent and 30 μg/ml DNAse. The mixture is incubated for 1 hour at room temperature with continuous mixing. The beads are washed again with PBS/AB/DNAse to collect the CD8+ T-cells. The DC are collected and centrifuged at 1300 rpm for 5-7 minutes, washed once with PBS with 1% BSA, counted and pulsed with 40 μg/ml of peptide at a cell concentration of 1-2×10⁶/ml in the presence of 3 μg/ml β₂-microglobulin for 4 hours at 20° C. The DC are then irradiated (4,200 rads), washed 1 time with medium and counted again.

Setting up induction cultures: 0.25 ml cytokine-generated DC (at 1×10⁵ cells/ml) are co-cultured with 0.25 ml of CD8+ T-cells (at 2×10⁶ cell/ml) in each well of a 48-well plate in the presence of 10 ng/ml of IL-7. Recombinant human IL-10 is added the next day at a final concentration of 10 ng/ml and rhuman IL-2 is added 48 hours later at 10 IU/ml.

Restimulation of the induction cultures with peptide-pulsed adherent cells: Seven and fourteen days after the primary induction, the cells are restimulated with peptide-pulsed adherent cells. The PBMCs are thawed and washed twice with RPMI and DNAse. The cells are resuspended at 5×10⁶ cells/ml and irradiated at ˜4200 rads. The PBMCs are plated at 2×10⁶ in 0.5 ml complete medium per well and incubated for 2 hours at 37° C. The plates are washed twice with RPMI by tapping the plate gently to remove the nonadherent cells and the adherent cells pulsed with 10 μg/ml of peptide in the presence of 3 μg/ml β₂ microglobulin in 0.25 ml RPMI/5% AB per well for 2 hours at 37° C. Peptide solution from each well is aspirated and the wells are washed once with RPMI. Most of the media is aspirated from the induction cultures (CD8+ cells) and brought to 0.5 ml with fresh media. The cells are then transferred to the wells containing the peptide-pulsed adherent cells. Twenty four hours later recombinant human IL-10 is added at a final concentration of 10 ng/ml and recombinant human IL2 is added the next day and again 2-3 days later at 50 IU/ml (Tsai et al., Critical Reviews in Immunology, 18(1-2):65-75, 1998). Seven days later, the cultures are assayed for CTL activity in a ⁵¹Cr release assay. In some experiments the cultures are assayed for peptide-specific recognition in the in situ IFNγ ELISA at the time of the second restimulation followed by assay of endogenous recognition 7 days later. After expansion, activity is measured in both assays for a side-by-side comparison.

Measurement of CTL Lytic Activity by ⁵¹Cr Release.

Seven days after the second restimulation, cytotoxicity is determined in a standard (5 hr) ⁵¹Cr release assay by assaying individual wells at a single E:T. Peptide-pulsed targets are prepared by incubating the cells with 10 μg/ml peptide overnight at 37° C.

Adherent target cells are removed from culture flasks with trypsin-EDTA. Target cells are labeled with 200 μCi of ⁵¹Cr sodium chromate (Dupont, Wilmington, Del.) for 1 hour at 37° C. Labeled target cells are resuspended at 10⁶ per ml and diluted 1:10 with K562 cells at a concentration of 3.3×10⁶/ml (an NK-sensitive erythroblastoma cell line used to reduce non-specific lysis). Target cells (100 μl) and effectors (100 μl) are plated in 96 well round-bottom plates and incubated for 5 hours at 37° C. At that time, 100 μl of supernatant are collected from each well and percent lysis is determined according to the formula: [(cpm of the test sample−cpm of the spontaneous ⁵¹Cr release sample)/(cpm of the maximal ⁵¹Cr release sample−cpm of the spontaneous ⁵¹Cr release sample)]×100.

Maximum and spontaneous release are determined by incubating the labeled targets with 1% Triton X-100 and media alone, respectively. A positive culture is defined as one in which the specific lysis (sample-background) is 10% or higher in the case of individual wells and is 15% or more at the two highest E:T ratios when expanded cultures are assayed.

In Situ Measurement of Human IFNγ Production as an Indicator of Peptide-specific and Endogenous Recognition

Immulon 2 plates are coated with mouse anti-human IFNγ monoclonal antibody (4 μg/ml 0.1M NaHCO₃, pH8.2) overnight at 4° C. The plates are washed with Ca²⁺, Mg²⁺-free PBS/0.05% Tween 20 and blocked with PBS/10% FCS for two hours, after which the CTLs (100 μl/well) and targets (100 μl/well) are added to each well, leaving empty wells for the standards and blanks (which received media only). The target cells, either peptide-pulsed or endogenous targets, are used at a concentration of 1×10⁶ cells/ml. The plates are incubated for 48 hours at 37° C. with 5% CO₂.

Recombinant human IFN-gamma is added to the standard wells starting at 400 pg or 1200 pg/100 microliter/well and the plate incubated for two hours at 37° C. The plates are washed and 100 μl of biotinylated mouse anti-human IFN-gamma monoclonal antibody (2 microgram/ml in PBS/3% FCS/0.05% Tween 20) are added and incubated for 2 hours at room temperature. After washing again, 100 microliter HRP-streptavidin (1:4000) are added and the plates incubated for one hour at room temperature. The plates are then washed 6× with wash buffer, 100 microliter/well developing solution (TMB 1:1) are added, and the plates allowed to develop for 5-15 minutes. The reaction is stopped with 50 microliter/well 1M H₃PO₄ and read at OD450. A culture is considered positive if it measured at least 50 pg of IFN-gamma/well above background and is twice the background level of expression.

CTL Expansion.

Those cultures that demonstrate specific lytic activity against peptide-pulsed targets and/or tumor targets are expanded over a two week period with anti-CD3. Briefly, 5×10⁴ CD8+ cells are added to a T25 flask containing the following: 1×10⁶ irradiated (4,200 rad) PBMC (autologous or allogeneic) per ml, 2×10⁵ irradiated (8,000 rad) EBV-transformed cells per ml, and OKT3 (anti-CD3) at 30 ng per ml in RPMI-1640 containing 10% (v/v) human AB serum, non-essential amino acids, sodium pyruvate, 25 μM 2-mercaptoethanol, L-glutamine and penicillin/streptomycin. Recombinant human IL2 is added 24 hours later at a final concentration of 200 IU/ml and every three days thereafter with fresh media at 50 IU/ml. The cells are split if the cell concentration exceeds 1×10⁶/ml and the cultures are assayed between days 13 and 15 at E:T ratios of 30, 10, 3 and 1:1 in the ⁵¹Cr release assay or at 1×10⁶/ml in the in situ IFNγ assay using the same targets as before the expansion.

Cultures are expanded in the absence of anti-CD3⁺ as follows. Those cultures that demonstrate specific lytic activity against peptide and endogenous targets are selected and 5×10⁴ CD8⁺ cells are added to a T25 flask containing the following: 1×10⁶ autologous PBMC per ml which have been peptide-pulsed with 10 μg/ml peptide for two hours at 37° C. and irradiated (4,200 rad); 2×10⁵ irradiated (8,000 rad) EBV-transformed cells per ml RPMI-1640 containing 10% (v/v) human AB serum, non-essential AA, sodium pyruvate, 25 mM 2-ME, L-glutamine and gentamicin.

Immunogenicity of A2 Supermotif-bearing Peptides

A2-supermotif cross-reactive binding peptides are tested in the cellular assay for the ability to induce peptide-specific CTL in normal individuals. In this analysis, a peptide is typically considered to be an epitope if it induces peptide-specific CTLs in at least individuals, and preferably, also recognizes the endogenously expressed peptide.

Immunogenicity can also be confirmed using PBMCs isolated from patients bearing a tumor that expresses a FIG. 2 protein. Briefly, PBMCs are isolated from patients, re-stimulated with peptide-pulsed monocytes and assayed for the ability to recognize peptide-pulsed target cells as well as transfected cells endogenously expressing the antigen.

Evaluation of A*03/A11 Immunogenicity

HLA-A3 supermotif-bearing cross-reactive binding peptides are also evaluated for immunogenicity using methodology analogous for that used to evaluate the immunogenicity of the HLA-A2 supermotif peptides.

Evaluation of B7 Immunogenicity

Immunogenicity screening of the B7-supertype cross-reactive binding peptides identified as set forth herein are confirmed in a manner analogous to the confirmation of A2- and A3-supermotif-bearing peptides.

Peptides bearing other supermotifs/motifs, e.g., HLA-A1, HLA-A24 etc. are also confirmed using similar methodology

Example 14 Implementation of the Extended Supermotif to Improve the Binding Capacity of Native Epitopes by Creating Analogs

HLA motifs and supermotifs (comprising primary and/or secondary residues) are useful in the identification and preparation of highly cross-reactive native peptides, as demonstrated herein. Moreover, the definition of HLA motifs and supermotifs also allows one to engineer highly cross-reactive epitopes by identifying residues within a native peptide sequence which can be analoged to confer upon the peptide certain characteristics, e.g. greater cross-reactivity within the group of HLA molecules that comprise a supertype, and/or greater binding affinity for some or all of those HLA molecules. Examples of analoging peptides to exhibit modulated binding affinity are set forth in this example.

Analoging at Primary Anchor Residues

Peptide engineering strategies are implemented to further increase the cross-reactivity of the epitopes. For example, the main anchors of A2-supermotif-bearing peptides are altered, for example, to introduce a preferred L, I, V, or M at position 2, and I or V at the C-terminus.

To analyze the cross-reactivity of the analog peptides, each engineered analog is initially tested for binding to the prototype A2 supertype allele A*0201, then, if A*0201 binding capacity is maintained, for A2-supertype cross-reactivity.

Alternatively, a peptide is confirmed as binding one or all supertype members and then analoged to modulate binding affinity to any one (or more) of the supertype members to add population coverage.

The selection of analogs for immunogenicity in a cellular screening analysis is typically further restricted by the capacity of the parent wild type (WT) peptide to bind at least weakly, i.e., bind at an IC₅₀ of 5000 nM or less, to three of more A2 supertype alleles. The rationale for this requirement is that the WT peptides must be present endogenously in sufficient quantity to be biologically relevant. Analoged peptides have been shown to have increased immunogenicity and cross-reactivity by T cells specific for the parent epitope (see, e.g., Parkhurst et al., J. Immunol. 157:2539, 1996; and Pogue et al., Proc. Natl. Acad. Sci. USA 92:8166, 1995).

In the cellular screening of these peptide analogs, it is important to confirm that analog-specific CTLs are also able to recognize the wild-type peptide and, when possible, target cells that endogenously express the epitope.

Analoging of HLA-A3 and B7-supermotif-bearing Peptides

Analogs of HLA-A3 supermotif-bearing epitopes are generated using strategies similar to those employed in analoging HLA-A2 supermotif-bearing peptides. For example, peptides binding to 3/5 of the A3-supertype molecules are engineered at primary anchor residues to possess a preferred residue (V, S, M, or A) at position 2.

The analog peptides are then tested for the ability to bind A*03 and A*11 (prototype A3 supertype alleles). Those peptides that demonstrate ≦500 nM binding capacity are then confirmed as having A3-supertype cross-reactivity.

Similarly to the A2- and A3-motif bearing peptides, peptides binding 3 or more B7-supertype alleles can be improved, where possible, to achieve increased cross-reactive binding or greater binding affinity or binding half life. B7 supermotif-bearing peptides are, for example, engineered to possess a preferred residue (V, I, L, or F) at the C-terminal primary anchor position, as demonstrated by Sidney et al. (J. Immunol. 157:3480-3490, 1996).

Analoging at primary anchor residues of other motif and/or supermotif-bearing epitopes is performed in a like manner.

The analog peptides are then be confirmed for immunogenicity, typically in a cellular screening assay. Again, it is generally important to demonstrate that analog-specific CTLs are also able to recognize the wild-type peptide and, when possible, targets that endogenously express the epitope.

Analoging at Secondary Anchor Residues

Moreover, HLA supermotifs are of value in engineering highly cross-reactive peptides and/or peptides that bind HLA molecules with increased affinity by identifying particular residues at secondary anchor positions that are associated with such properties. For example, the binding capacity of a B7 supermotif-bearing peptide with an F residue at position 1 is analyzed. The peptide is then analoged to, for example, substitute L for F at position 1. The analoged peptide is evaluated for increased binding affinity, binding half life and/or increased cross-reactivity. Such a procedure identifies analoged peptides with enhanced properties.

Engineered analogs with sufficiently improved binding capacity or cross-reactivity can also be tested for immunogenicity in HLA-B7-transgenic mice, following for example, IFA immunization or lipopeptide immunization. Analoged peptides are additionally tested for the ability to stimulate a recall response using PBMC from patients with protein(s) of FIG. 2–expressing tumors.

Other Analoging Strategies

Another form of peptide analoging, unrelated to anchor positions, involves the substitution of a cysteine with α-amino butyric acid. Due to its chemical nature, cysteine has the propensity to form disulfide bridges and sufficiently alter the peptide structurally so as to reduce binding capacity. Substitution of α-amino butyric acid for cysteine not only alleviates this problem, but has been shown to improve binding and crossbinding capabilities in some instances (see, e.g., the review by Sette et al., In: Persistent Viral Infections, Eds. R. Ahmed and I. Chen, John Wiley & Sons, England, 1999).

Thus, by the use of single amino acid substitutions, the binding properties and/or cross-reactivity of peptide ligands for HLA supertype molecules can be modulated.

Example 15 Identification of HLA-DR Binding Motifs in Proteins of FIG. 2

Peptide epitopes bearing an HLA class II supermotif or motif are identified and confirmed as outlined below using methodology similar to that described for HLA Class I peptides.

Selection of HLA-DR-Supermotif-Bearing Epitopes.

To identify HLA class II HTL epitopes derived from a protein of FIG. 2, a FIG. 2 antigen is analyzed for the presence of sequences bearing an HLA-DR-motif or supermotif. Specifically, 15-mer sequences are selected comprising a DR-supermotif, comprising a 9-mer core, and three-residue N- and C-terminal flanking regions (15 amino acids total).

Protocols for predicting peptide binding to DR molecules have been developed (Southwood et al., J. Immunol. 160:3363-3373, 1998). These protocols, specific for individual DR molecules, allow the scoring, and ranking, of 9-mer core regions. Each protocol not only scores peptide sequences for the presence of DR-supermotif primary anchors (i.e., at position 1 and position 6) within a 9-mer core, but also additionally evaluates sequences for the presence of secondary anchors. Using allele-specific selection tables (see, e.g., Southwood et al., ibid.), it has been found that these protocols efficiently select peptide sequences with a high probability of binding a particular DR molecule. Additionally, it has been found that performing these protocols in tandem, specifically those for DR1, DR4w4, and DR7, can efficiently select DR cross-reactive peptides.

The protein in FIG. 2–derived peptides identified above are tested for their binding capacity for various common HLA-DR molecules. All peptides are initially tested for binding to the DR molecules in the primary panel: DR1, DR4w4, and DR7. Peptides binding at least two of these three DR molecules are then tested for binding to DR2w2 β1, DR2w2 β2, DR6w19, and DR9 molecules in secondary assays. Finally, peptides binding at least two of the four secondary panel DR molecules, and thus cumulatively at least four of seven different DR molecules, are screened for binding to DR4w15, DR5w11, and DR8w2 molecules in tertiary assays. Peptides binding at least seven of the ten DR molecules comprising the primary, secondary, and tertiary screening assays are considered cross-reactive DR binders. Proteins in FIG. 2–derived peptides found to bind common HLA-DR alleles are of particular interest.

Selection of DR3 Motif Peptides

Because HLA-DR3 is an allele that is prevalent in Caucasian, Black, and Hispanic populations, DR3 binding capacity is a relevant criterion in the selection of HTL epitopes. Thus, peptides shown to be candidates may also be assayed for their DR3 binding capacity. However, in view of the binding specificity of the DR3 motif, peptides binding only to DR3 can also be considered as candidates for inclusion in a vaccine formulation.

To efficiently identify peptides that bind DR3, FIG. 2 antigens are analyzed for sequences carrying one of the two DR3-specific binding motifs reported by Geluk et al. (J. Immunol. 152:5742-5748, 1994). The corresponding peptides are then synthesized and confirmed as having the ability to bind DR3 with an affinity of 1 μM or better, i.e., less than 1 μM. Peptides are found that meet this binding criterion and qualify as HLA class II high affinity binders.

DR3 binding epitopes identified in this manner are included in vaccine compositions with DR supermotif-bearing peptide epitopes.

Similarly to the case of HLA class I motif-bearing peptides, the class II motif-bearing peptides are analoged to improve affinity or cross-reactivity. For example, aspartic acid at position 4 of the 9-mer core sequence is an optimal residue for DR3 binding, and substitution for that residue often improves DR 3 binding.

Example 16 Immunogenicity of HTL Epitopes Derived from a Protein of FIG. 2

This example determines immunogenic DR supermotif- and DR3 motif-bearing epitopes among those identified using the methodology set forth herein.

Immunogenicity of HTL epitopes are confirmed in a manner analogous to the determination of immunogenicity of CTL epitopes, by assessing the ability to stimulate HTL responses and/or by using appropriate transgenic mouse models. Immunogenicity is determined by screening for: 1.) in vitro primary induction using normal PBMC or 2.) recall responses from patients who have proteins of FIG. 2–expressing tumors.

Example 17 Calculation of Phenotypic Frequencies of HLA-supertypes in Various Ethnic Backgrounds to Determine Breadth of Population Coverage

This example illustrates the assessment of the breadth of population coverage of a vaccine composition comprised of multiple epitopes comprising multiple supermotifs and/or motifs.

In order to analyze population coverage, gene frequencies of HLA alleles are determined. Gene frequencies for each HLA allele are calculated from antigen or allele frequencies utilizing the binomial distribution formulae gf-1-(SQRT(1-af)) (see, e.g., Sidney et al., Human Immunol. 45:79-93, 1996). To obtain overall phenotypic frequencies, cumulative gene frequencies are calculated, and the cumulative antigen frequencies derived by the use of the inverse formula [af=1−(1−Cgf)²].

Where frequency data is not available at the level of DNA typing, correspondence to the serologically defined antigen frequencies is assumed. To obtain total potential supertype population coverage no linkage disequilibrium is assumed, and only alleles confirmed to belong to each of the supertypes are included (minimal estimates). Estimates of total potential coverage achieved by inter-loci combinations are made by adding to the A coverage the proportion of the non-A covered population that could be expected to be covered by the B alleles considered (e.g., total=A+B*(1−A)). Confirmed members of the A3-like supertype are A3, A11, A31, A*3301, and A*6801. Although the A3-like supertype may also include A34, A66, and A*7401, these alleles were not included in overall frequency calculations. Likewise, confirmed members of the A2-like supertype family are A*0201, A*0202, A*0203, A*0204, A*0205, A*0206, A*0207, A*6802, and A*6901. Finally, the B7-like supertype-confirmed alleles are: B7, B*3501-03, B51, B*5301, B*5401, B*5501-2, B*5601, B*6701, and B*7801 (potentially also B*1401, B*3504-06, B*4201, and B*5602).

Population coverage achieved by combining the A2-, A3- and B7-supertypes is approximately 86% in five major ethnic groups. Coverage may be extended by including peptides bearing the A1 and A24 motifs. On average, A1 is present in 12% and A24 in 29% of the population across five different major ethnic groups (Caucasian, North American Black, Chinese, Japanese, and Hispanic). Together, these alleles are represented with an average frequency of 39% in these same ethnic populations. The total coverage across the major ethnicities when A1 and A24 are combined with the coverage of the A2-, A3- and B7-supertype alleles is >95%. An analogous approach can be used to estimate population coverage achieved with combinations of class II motif-bearing epitopes.

Immunogenicity studies in humans (e.g., Bertoni et al., J. Clin. Invest. 100:503, 1997; Doolan et al., Immunity 7:97, 1997; and Threlkeld et al., J. Immunol. 159:1648, 1997) have shown that highly cross-reactive binding peptides are almost always recognized as epitopes. The use of highly cross-reactive binding peptides is an important selection criterion in identifying candidate epitopes for inclusion in a vaccine that is immunogenic in a diverse population.

With a sufficient number of epitopes (as disclosed herein and from the art), an average population coverage is predicted to be greater than 95% in each of five major ethnic populations. The game theory Monte Carlo simulation analysis, which is known in the art (see e.g., Osborne, M. J. and Rubinstein, A. “A course in game theory” MIT Press, 1994), can be used to estimate what percentage of the individuals in a population comprised of the Caucasian, North American Black, Japanese, Chinese, and Hispanic ethnic groups would recognize the vaccine epitopes described herein. A preferred percentage is 90%. A more preferred percentage is 95%.

Example 18 CTL Recognition of Endogenously Processed Antigens After Priming

This example confirms that CTL induced by native or analoged peptide epitopes identified and selected as described herein recognize endogenously synthesized, i.e., native antigens.

Effector cells isolated from transgenic mice that are immunized with peptide epitopes, for example HLA-A2 supermotif-bearing epitopes, are re-stimulated in vitro using peptide-coated stimulator cells. Six days later, effector cells are assayed for cytotoxicity and the cell lines that contain peptide-specific cytotoxic activity are further re-stimulated. An additional six days later, these cell lines are tested for cytotoxic activity on ⁵¹Cr labeled Jurkat-A2.1/K^(b) target cells in the absence or presence of peptide, and also tested on ⁵¹Cr labeled target cells bearing the endogenously synthesized antigen, i.e. cells that are stably transfected with a gene of FIG. 2–related expression vector.

The results demonstrate that CTL lines obtained from animals primed with peptide epitopes recognize endogenously synthesized FIG. 2 antigens. The choice of transgenic mouse model to be used for such an analysis depends upon the epitope(s) that are being evaluated. In addition to HLA-A*0201/K^(b) transgenic mice, several other transgenic mouse models including mice with human A11, which may also be used to evaluate A3 epitopes, and B7 alleles have been characterized and others (e.g., transgenic mice for HLA-A1 and A24) are being developed. HLA-DR1 and HLA-DR3 mouse models have also been developed, which may be used to evaluate HTL epitopes.

Example 19 Activity of CTL-HTL Conjugated Epitopes in Transgenic Mice

This example illustrates the induction of CTLs and HTLs in transgenic mice, by use of a protein of FIG. 2–derived CTL and HTL peptide vaccine compositions. The vaccine compositions used herein comprise peptides to be administered to a patient with a protein of FIG. 2–expressing tumor. The peptide composition can comprise multiple CTL and/or HTL epitopes. The epitopes are identified using methodology as described herein. This example also illustrates that enhanced immunogenicity can be achieved by inclusion of one or more HTL epitopes in a CTL vaccine composition; such a peptide composition can comprise an HTL epitope conjugated to a CTL epitope. The CTL epitope can be one that binds to multiple HLA family members at an affinity of 500 nM or less, or analogs of that epitope. The peptides may be lipidated, if desired.

Immunization procedures: Immunization of transgenic mice is performed as described (Alexander et al, J. Immunol. 159:4753-4761, 1997). For example, A2/K^(b) mice, which are transgenic for the human HLA A2.1 allele and are used to confirm the immunogenicity of HLA-A*0201 motif- or HLA-A2 supermotif-bearing epitopes, and are primed subcutaneously (base of the tail) with a 0.1 ml of peptide in Incomplete Freund's Adjuvant, or if the peptide composition is a lipidated CTL/HTL conjugate, in DMSO/saline, or if the peptide composition is a polypeptide, in PBS or Incomplete Freund's Adjuvant. Seven days after priming, splenocytes obtained from these animals are restimulated with syngenic irradiated LPS-activated lymphoblasts coated with peptide.

Cell lines: Target cells for peptide-specific cytotoxicity assays are Jurkat cells transfected with the HLA-A2.1/K^(b) chimeric gene (e.g., Vitiello et al., J. Exp. Med 173:1007, 1991)

In vitro CTL activation: One week after priming, spleen cells (30×10⁶ cells/flask) are co-cultured at 37° C. with syngeneic, irradiated (3000 rads), peptide coated lymphoblasts (10×10⁶ cells/flask) in 10 ml of culture medium/T25 flask. After six days, effector cells are harvested and assayed for cytotoxic activity.

Assay for cytotoxic activity: Target cells (1.0 to 1.5×10⁶) are incubated at 37° C. in the presence of 200 μl of ⁵¹Cr. After 60 minutes, cells are washed three times and resuspended in R10 medium. Peptide is added where required at a concentration of 1 μg/ml. For the assay, 10⁴ ⁵¹Cr-labeled target cells are added to different concentrations of effector cells (final volume of 200 μl) in U-bottom 96-well plates. After a six hour incubation period at 37° C., a 0.1 ml aliquot of supernatant is removed from each well and radioactivity is determined in a Micromedic automatic gamma counter. The percent specific lysis is determined by the formula: percent specific release=100× (experimental release−spontaneous release)/(maximum release−spontaneous release). To facilitate comparison between separate CTL assays run under the same conditions, % ⁵¹Cr release data is expressed as lytic units/10⁶ cells. One lytic unit is arbitrarily defined as the number of effector cells required to achieve 30% lysis of 10,000 target cells in a six hour ⁵¹Cr release assay. To obtain specific lytic units/10⁶, the lytic units/10⁶ obtained in the absence of peptide is subtracted from the lytic units/10⁶ obtained in the presence of peptide. For example, if 30% ⁵¹Cr release is obtained at the effector (E): target (T) ratio of 50:1 (i.e., 5×10⁵ effector cells for 10,000 targets) in the absence of peptide and 5:1 (i.e., 5×10⁴ effector cells for 10,000 targets) in the presence of peptide, the specific lytic units would be: [(1/50,000)−(1/500,000)]×10⁶=18 LU.

The results are analyzed to assess the magnitude of the CTL responses of animals injected with the immunogenic CTL/HTL conjugate vaccine preparation and are compared to the magnitude of the CTL response achieved using, for example, CTL epitopes as outlined above in the Example entitled “Confirmation of Immunogenicity”. Analyses similar to this may be performed to confirm the immunogenicity of peptide conjugates containing multiple CTL epitopes and/or multiple HTL epitopes. In accordance with these procedures, it is found that a CTL response is induced, and concomitantly that an HTL response is induced upon administration of such compositions.

Example 20 Selection of CTL and HTL Epitopes for Inclusion in a Vaccine Specific for a Protein of FIG. 2

This example illustrates a procedure for selecting peptide epitopes for vaccine compositions of the invention. The peptides in the composition can be in the form of a nucleic acid sequence, either single or one or more sequences (i.e., minigene) that encodes peptide(s), or can be single and/or polyepitopic peptides.

The following principles are utilized when selecting a plurality of epitopes for inclusion in a vaccine composition. Each of the following principles is balanced in order to make the selection.

Epitopes are selected which, upon administration, mimic immune responses that are correlated with FIG. 2 protein clearance. The number of epitopes used depends on observations of patients who spontaneously clear a FIG. 2 protein. For example, if it has been observed that patients who spontaneously clear a FIG. 2 protein generate an immune response to at least three (3) epitopes from a protein of FIG. 2 antigen, then at least three epitopes should be included for HLA class I. A similar rationale is used to determine HLA class II epitopes.

Epitopes are often selected that have a binding affinity of an IC₅₀ of 500 nM or less for an HLA class I molecule, or for class II, an IC₅₀ of 1000 nM or less; or HLA Class I peptides with high binding scores.

In order to achieve broad coverage of the vaccine through out a diverse population, sufficient supermotif bearing peptides, or a sufficient array of allele-specific motif bearing peptides, are selected to give broad population coverage. In one embodiment, epitopes are selected to provide at least 80% population coverage. A Monte Carlo analysis, a statistical evaluation known in the art, can be employed to assess breadth, or redundancy, of population coverage.

When creating polyepitopic compositions, or a minigene that encodes same, it is typically desirable to generate the smallest peptide possible that encompasses the epitopes of interest. The principles employed are similar, if not the same, as those employed when selecting a peptide comprising nested epitopes. For example, a protein sequence for the vaccine composition is selected because it has maximal number of epitopes contained within the sequence, i.e., it has a high concentration of epitopes. Epitopes may be nested or overlapping (i.e., frame shifted relative to one another). For example, with overlapping epitopes, two 9-mer epitopes and one 10-mer epitope can be present in a 10 amino acid peptide. Each epitope can be exposed and bound by an HLA molecule upon administration of such a peptide. A multi-epitopic, peptide can be generated synthetically, recombinantly, or via cleavage from the native source. Alternatively, an analog can be made of this native sequence, whereby one or more of the epitopes comprise substitutions that alter the cross-reactivity and/or binding affinity properties of the polyepitopic peptide. Such a vaccine composition is administered for therapeutic or prophylactic purposes. This embodiment provides for the possibility that an as yet undiscovered aspect of immune system processing will apply to the native nested sequence and thereby facilitate the production of therapeutic or prophylactic immune response-inducing vaccine compositions. Additionally such an embodiment provides for the possibility of motif-bearing epitopes for an HLA makeup that is presently unknown. Furthermore, this embodiment (absent the creating of any analogs) directs the immune response to multiple peptide sequences that are actually present in FIG. 2 proteins, thus avoiding the need to evaluate any junctional epitopes. Lastly, the embodiment provides an economy of scale when producing nucleic acid vaccine compositions. Related to this embodiment, computer programs can be derived in accordance with principles in the art, which identify in a target sequence, the greatest number of epitopes per sequence length.

A vaccine composition comprised of selected peptides, when administered, is safe, efficacious, and elicits an immune response similar in magnitude to an immune response that controls or clears cells that bear or overexpress a FIG. 2 protein.

Example 21 Construction of “Minigene” Multi-Epitope DNA Plasmids

This example discusses the construction of a minigene expression plasmid. Minigene plasmids may, of course, contain various configurations of B cell, CTL and/or HTL epitopes or epitope analogs as described herein.

A minigene expression plasmid typically includes multiple CTL and HTL peptide epitopes. In the present example, HLA-A2, -A3, -B7 supermotif-bearing peptide epitopes and HLA-A1 and -A24 motif-bearing peptide epitopes are used in conjunction with DR supermotif-bearing epitopes and/or DR3 epitopes. HLA class I supermotif or motif-bearing peptide epitopes derived from a protein of FIG. 2, are selected such that multiple supermotifs/motifs are represented to ensure broad population coverage. Similarly, HLA class II epitopes are selected from a FIG. 2 protein to provide broad population coverage, i.e. both HLA DR-1-4-7 supermotif-bearing epitopes and HLA DR-3 motif-bearing epitopes are selected for inclusion in the minigene construct. The selected CTL and HTL epitopes are then incorporated into a minigene for expression in an expression vector.

Such a construct may additionally include sequences that direct the HTL epitopes to the endoplasmic reticulum. For example, the Ii protein may be fused to one or more HTL epitopes as described in the art, wherein the CLIP sequence of the Ii protein is removed and replaced with an HLA class II epitope sequence so that HLA class II epitope is directed to the endoplasmic reticulum, where the epitope binds to an HLA class II molecules.

This example illustrates the methods to be used for construction of a minigene-bearing expression plasmid. Other expression vectors that may be used for minigene compositions are available and known to those of skill in the art.

The minigene DNA plasmid of this example contains a consensus Kozak sequence and a consensus murine kappa Ig-light chain signal sequence followed by CTL and/or HTL epitopes selected in accordance with principles disclosed herein. The sequence encodes an open reading frame fused to the Myc and His antibody epitope tag coded for by the pcDNA 3.1 Myc-His vector.

Overlapping oligonucleotides that can, for example, average about 70 nucleotides in length with 15 nucleotide overlaps, are synthesized and HPLC-purified. The oligonucleotides encode the selected peptide epitopes as well as appropriate linker nucleotides, Kozak sequence, and signal sequence. The final multiepitope minigene is assembled by extending the overlapping oligonucleotides in three sets of reactions using PCR. A Perkin/Elmer 9600 PCR machine is used and a total of 30 cycles are performed using the following conditions: 95° C. for 15 sec, annealing temperature (5° below the lowest calculated Tm of each primer pair) for 30 sec, and 72° C. for 1 min.

For example, a minigene is prepared as follows. For a first PCR reaction, 5 μg of each of two oligonucleotides are annealed and extended: In an example using eight oligonucleotides, i.e., four pairs of primers, oligonucleotides 1+2, 3+4, 5+6, and 7+8 are combined in 100 μl reactions containing Pfu polymerase buffer (1×=10 mM KCL, 10 mM (NH4)₂SO₄, 20 mM Tris-chloride, pH 8.75, 2 mM MgSO₄, 0.1% Triton X-100, 100 μg/ml BSA), 0.25 mM each dNTP, and 2.5 U of Pfu polymerase. The full-length dimer products are gel-purified, and two reactions containing the product of 1+2 and 3+4, and the product of 5+6 and 7+8 are mixed, annealed, and extended for 10 cycles. Half of the two reactions are then mixed, and 5 cycles of annealing and extension carried out before flanking primers are added to amplify the full length product. The full-length product is gel-purified and cloned into pCR-blunt (Invitrogen) and individual clones are screened by sequencing.

Example 22 The Plasmid Construct and the Degree to which it Induces Immunogenicity

The degree to which a plasmid construct, for example a plasmid constructed in accordance with the previous Example, is able to induce immunogenicity is confirmed in vitro by determining epitope presentation by APC following transduction or transfection of the APC with an epitope-expressing nucleic acid construct. Such a study determines “antigenicity” and allows the use of human APC. The assay determines the ability of the epitope to be presented by the APC in a context that is recognized by a T cell by quantifying the density of epitope-HLA class I complexes on the cell surface. Quantitation can be performed by directly measuring the amount of peptide eluted from the APC (see, e.g., Sijts et al., J. Immunol. 156:683-692, 1996; Demotz et al., Nature 342:682-684, 1989); or the number of peptide-HLA class I complexes can be estimated by measuring the amount of lysis or lymphokine release induced by diseased or transfected target cells, and then determining the concentration of peptide necessary to obtain equivalent levels of lysis or lymphokine release (see, e.g., Kageyama et al., J. Immunol. 154:567-576, 1995).

Alternatively, immunogenicity is confirmed through in vivo injections into mice and subsequent in vitro assessment of CTL and HTL activity, which are analyzed using cytotoxicity and proliferation assays, respectively, as detailed e.g., in Alexander et al., Immunity 1:751-761, 1994.

For example, to confirm the capacity of a DNA minigene construct containing at least one HLA-A2 supermotif peptide to induce CTLs in vivo, HLA-A2.1/K^(b) transgenic mice, for example, are immunized intramuscularly with 100 μg of naked cDNA. As a means of comparing the level of CTLs induced by cDNA immunization, a control group of animals is also immunized with an actual peptide composition that comprises multiple epitopes synthesized as a single polypeptide as they would be encoded by the minigene.

Splenocytes from immunized animals are stimulated twice with each of the respective compositions (peptide epitopes encoded in the minigene or the polyepitopic peptide), then assayed for peptide-specific cytotoxic activity in a ⁵¹Cr release assay. The results indicate the magnitude of the CTL response directed against the A2-restricted epitope, thus indicating the in vivo immunogenicity of the minigene vaccine and polyepitopic vaccine.

It is, therefore, found that the minigene elicits immune responses directed toward the HLA-A2 supermotif peptide epitopes as does the polyepitopic peptide vaccine. A similar analysis is also performed using other HLA-A3 and HLA-B7 transgenic mouse models to assess CTL induction by HLA-A3 and HLA-B7 motif or supermotif epitopes, whereby it is also found that the minigene elicits appropriate immune responses directed toward the provided epitopes.

To confirm the capacity of a class II epitope-encoding minigene to induce HTLs in vivo, DR transgenic mice, or for those epitopes that cross react with the appropriate mouse MHC molecule, I-A^(b)-restricted mice, for example, are immunized intramuscularly with 100 μg of plasmid DNA. As a means of comparing the level of HTLs induced by DNA immunization, a group of control animals is also immunized with an actual peptide composition emulsified in complete Freund's adjuvant. CD4+ T cells, i.e. HTLs, are purified from splenocytes of immunized animals and stimulated with each of the respective compositions (peptides encoded in the minigene). The HTL response is measured using a ³H-thymidine incorporation proliferation assay, (see, e.g., Alexander et al. Immunity 1:751-761, 1994). The results indicate the magnitude of the HTL response, thus demonstrating the in vivo immunogenicity of the minigene.

DNA minigenes, constructed as described in the previous Example, can also be confirmed as a vaccine in combination with a boosting agent using a prime boost protocol. The boosting agent can consist of recombinant protein (e.g., Barnett et al., Aids Res. and Human Retroviruses 14, Supplement 3:S299-S309, 1998) or recombinant vaccinia, for example, expressing a minigene or DNA encoding the complete protein of interest (see, e.g., Hanke et al., Vaccine 16:439-445, 1998; Sedegah et al., Proc. Natl. Acad. Sci USA 95:7648-53, 1998; Hanke and McMichael, Immunol. Letters 66:177-181, 1999; and Robinson et al., Nature Med 5:526-34, 1999).

For example, the efficacy of the DNA minigene used in a prime boost protocol is initially evaluated in transgenic mice. In this example, A2.1/K^(b) transgenic mice are immunized 1M with 100 μg of a DNA minigene encoding the immunogenic peptides including at least one HLA-A2 supermotif-bearing peptide. After an incubation period (ranging from 3-9 weeks), the mice are boosted IP with 10⁷ pfu/mouse of a recombinant vaccinia virus expressing the same sequence encoded by the DNA minigene. Control mice are immunized with 100 μg of DNA or recombinant vaccinia without the minigene sequence, or with DNA encoding the minigene, but without the vaccinia boost. After an additional incubation period of two weeks, splenocytes from the mice are immediately assayed for peptide-specific activity in an ELISPOT assay. Additionally, splenocytes are stimulated in vitro with the A2-restricted peptide epitopes encoded in the minigene and recombinant vaccinia, then assayed for peptide-specific activity in an alpha, beta and/or gamma IFN ELISA.

It is found that the minigene utilized in a prime-boost protocol elicits greater immune responses toward the HLA-A2 supermotif peptides than with DNA alone. Such an analysis can also be performed using HLA-A11 or HLA-B7 transgenic mouse models to assess CTL induction by HLA-A3 or HLA-B7 motif or supermotif epitopes. The use of prime boost protocols in humans is described below in the Example entitled “Induction of CTL Responses Using a Prime Boost Protocol.”

Example 23 Peptide Compositions for Prophylactic Uses

Vaccine compositions of the present invention can be used to prevent a gene of FIG. 2 expression in persons who are at risk for tumors that bear this antigen. For example, a polyepitopic peptide epitope composition (or a nucleic acid comprising the same) containing multiple CTL and HTL epitopes such as those selected in the above Examples, which are also selected to target greater than 80% of the population, is administered to individuals at risk for a protein of FIG. 2–associated tumor.

For example, a peptide-based composition is provided as a single polypeptide that encompasses multiple epitopes. The vaccine is typically administered in a physiological solution that comprises an adjuvant, such as Incomplete Freunds Adjuvant. The dose of peptide for the initial immunization is from about 1 to about 50,000 μg, generally 100-5,000 μg, for a 70 kg patient. The initial administration of vaccine is followed by booster dosages at 4 weeks followed by evaluation of the magnitude of the immune response in the patient, by techniques that determine the presence of epitope-specific CTL populations in a PBMC sample. Additional booster doses are administered as required. The composition is found to be both safe and efficacious as a prophylaxis against protein of FIG. 2–associated disease.

Alternatively, a composition typically comprising transfecting agents is used for the administration of a nucleic acid-based vaccine in accordance with methodologies known in the art and disclosed herein.

Example 24 Polyepitopic Vaccine Compositions Derived from Native Protein Sequence of FIG. 2

A native FIG. 2 protein sequence is analyzed, preferably using computer algorithms defined for each class I and/or class II supermotif or motif, to identify “relatively short” regions of the polyprotein that comprise multiple epitopes. The “relatively short” regions are preferably less in length than an entire native antigen. This relatively short sequence that contains multiple distinct or overlapping, “nested” epitopes is selected; it can be used to generate a minigene construct. The construct is engineered to express the peptide, which corresponds to the native protein sequence. The “relatively short” peptide is generally less than 250 amino acids in length, often less than 100 amino acids in length, preferably less than 75 amino acids in length, and more preferably less than 50 amino acids in length. The protein sequence of the vaccine composition is selected because it has maximal number of epitopes contained within the sequence, i.e., it has a high concentration of epitopes. As noted herein, epitope motifs may be nested or overlapping (i.e., frame shifted relative to one another). For example, with overlapping epitopes, two 9-mer epitopes and one 10-mer epitope can be present in a 10 amino acid peptide. Such a vaccine composition is administered for therapeutic or prophylactic purposes.

The vaccine composition will include, for example, multiple CTL epitopes from a protein antigen of the invention and at least one HTL epitope. This polyepitopic native sequence is administered either as a peptide or as a nucleic acid sequence which encodes the peptide. Alternatively, an analog can be made of this native sequence, whereby one or more of the epitopes comprise substitutions that alter the cross-reactivity and/or binding affinity properties of the polyepitopic peptide.

The embodiment of this example provides for the possibility that an as yet undiscovered aspect of immune system processing will apply to the native nested sequence and thereby facilitate the production of therapeutic or prophylactic immune response-inducing vaccine compositions. Additionally such an embodiment provides for the possibility of motif-bearing epitopes for an HLA makeup that is presently unknown. Furthermore, this embodiment (excluding an analoged embodiment) directs the immune response to multiple peptide sequences that are actually present in native proteins of the invention, thus avoiding the need to evaluate any junctional epitopes. Lastly, the embodiment provides an economy of scale when producing peptide or nucleic acid vaccine compositions.

Related to this embodiment, computer programs are available in the art which can be used to identify in a target sequence, the greatest number of epitopes per sequence length.

Example 25 Polyepitopic Vaccine Compositions from Multiple Antigens

The protein peptide epitopes of the present invention are used in conjunction with epitopes from other target tumor-associated antigens (such as from one or more proteins of FIG. 2), to create a vaccine composition that is useful for the prevention or treatment of cancer that expresses protein(s) of the invention and such other antigens. For example, a vaccine composition can be provided as a single polypeptide that incorporates multiple epitopes from a protein of the invention as well as tumor-associated antigens that are often expressed with the particular target cancer that is also associated with expression of a protein of the invention, or can be administered as a composition comprising a cocktail of one or more discrete epitopes. Alternatively, the vaccine can be administered as a minigene construct or as dendritic cells which have been loaded with the peptide epitopes in vitro.

Example 26 Use of Peptides to Evaluate an Immune Response

Peptides of the invention may be used to analyze an immune response for the presence of specific antibodies, CTL or HTL directed to a protein of the invention. Such an analysis can be performed in a manner described by Ogg et al., Science 279:2103-2106, 1998. In this Example, peptides in accordance with the invention are used as a reagent for diagnostic or prognostic purposes, not as an immunogen.

In this example highly sensitive human leukocyte antigen tetrameric complexes (“tetramers”) are used for a cross-sectional analysis of, for example, a protein of FIG. 2 HLA-A*0201-specific CTL frequencies from HLA A*0201-positive individuals at different stages of disease or following immunization comprising a protein of FIG. 2 peptide containing an A*0201 motif. Tetrameric complexes are synthesized as described (Musey et al., N. Engl. J. Med. 337:1267, 1997). Briefly, purified HLA heavy chain (A*0201 in this example) and β2-microglobulin are synthesized by means of a prokaryotic expression system. The heavy chain is modified by deletion of the transmembrane-cytosolic tail and COOH-terminal addition of a sequence containing a BirA enzymatic biotinylation site. The heavy chain, β2-microglobulin, and peptide are refolded by dilution. The 45-kD refolded product is isolated by fast protein liquid chromatography and then biotinylated by BirA in the presence of biotin (Sigma, St. Louis, Mo.), adenosine 5′ triphosphate and magnesium. Streptavidin-phycoerythrin conjugate is added in a 1:4 molar ratio, and the tetrameric product is concentrated to 1 mg/ml. The resulting product is referred to as tetramer-phycoerythrin.

For the analysis of patient blood samples, approximately one million PBMCs are centrifuged at 300 g for 5 minutes and resuspended in 50 μl of cold phosphate-buffered saline. Tri-color analysis is performed with the tetramer-phycoerythrin, along with anti-CD8-Tricolor, and anti-CD38. The PBMCs are incubated with tetramer and antibodies on ice for 30 to 60 min and then washed twice before formaldehyde fixation. Gates are applied to contain >99.98% of control samples. Controls for the tetramers include both A*0201-negative individuals and A*0201-positive non-diseased donors. The percentage of cells stained with the tetramer is then determined by flow cytometry. The results indicate the number of cells in the PBMC sample that contain epitope-restricted CTLs, thereby readily indicating the extent of immune response to the protein of the invention epitopes, and thus the status of exposure to proteins of the invention, or exposure to a vaccine that elicits a protective or therapeutic response.

Example 27 Use of Peptide Epitopes to Evaluate Recall Responses

The peptide epitopes of the invention are used as reagents to evaluate T cell responses, such as acute or recall responses, in patients. Such an analysis may be performed on patients who have recovered from a protein of the invention-associated disease or who have been vaccinated with a protein of the invention vaccine.

For example, the class I restricted CTL response of persons who have been vaccinated may be analyzed. The vaccine may be any protein of the invention vaccine. PBMC are collected from vaccinated individuals and HLA typed. Appropriate peptide epitopes of the invention that, optimally, bear supermotifs to provide cross-reactivity with multiple HLA supertype family members, are then used for analysis of samples derived from individuals who bear that HLA type.

PBMC from vaccinated individuals are separated on Ficoll-Histopaque density gradients (Sigma Chemical Co., St. Louis, Mo.), washed three times in HBSS (GIBCO Laboratories), resuspended in RPMI-1640 (GIBCO Laboratories) supplemented with L-glutamine (2 mM), penicillin (50 U/ml), streptomycin (50 μg/ml), and Hepes (10 mM) containing 10% heat-inactivated human AB serum (complete RPMI) and plated using microculture formats. A synthetic peptide comprising an epitope of the invention is added at 10 μg/ml to each well and HBV core 128-140 epitope is added at 1 μg/ml to each well as a source of T cell help during the first week of stimulation.

In the microculture format, 4×10⁵ PBMC are stimulated with peptide in 8 replicate cultures in 96-well round bottom plate in 100 μl/well of complete RPMI. On days 3 and 10, 100 μl of complete RPMI and 20 U/ml final concentration of rIL-2 are added to each well. On day 7 the cultures are transferred into a 96-well flat-bottom plate and restimulated with peptide, rIL-2 and 10⁵ irradiated (3,000 rad) autologous feeder cells. The cultures are tested for cytotoxic activity on day 14. A positive CTL response requires two or more of the eight replicate cultures to display greater than 10% specific ⁵¹Cr release, based on comparison with non-diseased control subjects as previously described (Rehermann, et al., Nature Med. 2:1104, 1108, 1996; Rehermann et al., J. Clin. Invest. 97:1655-1665, 1996; and Rehermann et al. J. Clin. Invest. 98:1432-1440, 1996).

Target cell lines are autologous and allogeneic EBV-transformed B-LCL that are either purchased from the American Society for Histocompatibility and Immunogenetics (ASHI, Boston, Mass.) or established from the pool of patients as described (Guilhot, et al. J. Virol. 66:2670-2678, 1992).

Cytotoxicity assays are performed in the following manner. Target cells consist of either allogeneic HLA-matched or autologous EBV-transformed B lymphoblastoid cell line that are incubated overnight with the synthetic peptide epitope of the invention at 10 μM, and labeled with 100 μCi of ⁵¹Cr (Amersham Corp., Arlington Heights, Ill.) for 1 hour after which they are washed four times with HBSS.

Cytolytic activity is determined in a standard 4-h, split well ⁵¹Cr release assay using U-bottomed 96 well plates containing 3,000 targets/well. Stimulated PBMC are tested at effector/target (E/T) ratios of 20-50:1 on day 14. Percent cytotoxicity is determined from the formula: 100×[(experimental release-spontaneous release)/maximum release-spontaneous release)]. Maximum release is determined by lysis of targets by detergent (2% Triton X-100; Sigma Chemical Co., St. Louis, Mo.). Spontaneous release is <25% of maximum release for all experiments.

The results of such an analysis indicate the extent to which HLA-restricted CTL populations have been stimulated by previous exposure to proteins of the invention or a protein of the invention-related vaccine.

Similarly, Class II restricted HTL responses may also be analyzed. Purified PBMC are cultured in a 96-well flat bottom plate at a density of 1.5×10⁵ cells/well and are stimulated with 10 μg/ml synthetic peptide of the invention, a whole protein of the invention antigens, or PHA. Cells are routinely plated in replicates of 4-6 wells for each condition. After seven days of culture, the medium is removed and replaced with fresh medium containing 10 U/ml IL-2. Two days later, 1 μCi ³H-thymidine is added to each well and incubation is continued for an additional 18 hours. Cellular DNA is then harvested on glass fiber mats and analyzed for ³H-thymidine incorporation. Antigen-specific T cell proliferation is calculated as the ratio of ³H-thymidine incorporation in the presence of antigen divided by the ³H-thymidine incorporation in the absence of antigen.

Example 28 Induction of Specific CTL Response in Humans

A human clinical trial for an immunogenic composition comprising CTL and HTL epitopes of the invention is set up as an IND Phase I, dose escalation study and carried out as a randomized, double-blind, placebo-controlled trial. Such a trial is designed, for example, as follows:

A total of about 27 individuals are enrolled and divided into 3 groups:

-   -   Group I: 3 subjects are injected with placebo and 6 subjects are         injected with 5 μg of peptide composition;     -   Group II: 3 subjects are injected with placebo and 6 subjects         are injected with 50 μg peptide composition;     -   Group III: 3 subjects are injected with placebo and 6 subjects         are injected with 500 μg of peptide composition.

After 4 weeks following the first injection, all subjects receive a booster inoculation at the same dosage.

The endpoints measured in this study relate to the safety and tolerability of the peptide composition as well as its immunogenicity. Cellular immune responses to the peptide composition are an index of the intrinsic activity of this the peptide composition, and can therefore be viewed as a measure of biological efficacy. The following summarize the clinical and laboratory data that relate to safety and efficacy endpoints.

Safety: The incidence of adverse events is monitored in the placebo and drug treatment group and assessed in terms of degree and reversibility.

Evaluation of Vaccine Efficacy: For evaluation of vaccine efficacy, subjects are bled before and after injection. Peripheral blood mononuclear cells are isolated from fresh heparinized blood by Ficoll-Hypaque density gradient centrifugation, aliquoted in freezing media and stored frozen. Samples are assayed for CTL and HTL activity.

The vaccine is found to be both safe and efficacious.

Example 29 Phase it Trials in Patients Expressing a Gene of the Invention

Phase II trials are performed to study the effect of administering the CTL-HTL peptide compositions to patients having a cancer that expresses genes of the invention. The main objectives of the trial are to determine an effective dose and regimen for inducing CTLs in cancer patients that express a gene(s) of the invention, to establish the safety of inducing a CTL and HTL response in these patients, and to see to what extent activation of CTLs improves the clinical picture of these patients, as manifested, e.g., by the reduction and/or shrinking of lesions. Such a study is designed, for example, as follows:

The studies are performed in multiple centers. The trial design is an open-label, uncontrolled, dose escalation protocol wherein the peptide composition is administered as a single dose followed six weeks later by a single booster shot of the same dose. The dosages are 50, 500 and 5,000 micrograms per injection. Drug-associated adverse effects (severity and reversibility) are recorded.

There are three patient groupings. The first group is injected with 50 micrograms of the peptide composition and the second and third groups with 500 and 5,000 micrograms of peptide composition, respectively. The patients within each group range in age from 21-65 and represent diverse ethnic backgrounds. All of them have a tumor that expresses a gene of the invention.

Clinical manifestations or antigen-specific T-cell responses are monitored to assess the effects of administering the peptide compositions. The vaccine composition is found to be both safe and efficacious in the treatment of a gene of the invention-associated disease.

Example 30 Induction of CTL Responses Using a Prime Boost Protocol

A prime boost protocol similar in its underlying principle to that used to confirm the efficacy of a DNA vaccine in transgenic mice, such as described above in the Example entitled “The Plasmid Construct and the Degree to Which It Induces Immunogenicity,” can also be used for the administration of the vaccine to humans. Such a vaccine regimen can include an initial administration of, for example, naked DNA followed by a boost using recombinant virus encoding the vaccine, or recombinant protein/polypeptide or a peptide mixture administered in an adjuvant.

For example, the initial immunization may be performed using an expression vector, such as that constructed in the Example entitled “Construction of ‘Minigene’ Multi-Epitope DNA Plasmids” in the form of naked nucleic acid administered IM (or SC or ID) in the amounts of 0.5-5 mg at multiple sites. The nucleic acid (0.1 to 1000 μg) can also be administered using a gene gun. Following an incubation period of 34 weeks, a booster dose is then administered. The booster can be recombinant fowlpox virus administered at a dose of 5-10⁷ to 5×10⁹ pfu. An alternative recombinant virus, such as an MVA, canarypox, adenovirus, or adeno-associated virus, can also be used for the booster, or the polyepitopic protein or a mixture of the peptides can be administered. For evaluation of vaccine efficacy, patient blood samples are obtained before immunization as well as at intervals following administration of the initial vaccine and booster doses of the vaccine. Peripheral blood mononuclear cells are isolated from fresh heparinized blood by Ficoll-Hypaque density gradient centrifugation, aliquoted in freezing media and stored frozen. Samples are assayed for CTL and HTL activity.

Analysis of the results indicates that a magnitude of response sufficient to achieve a therapeutic or protective immunity against of FIG. 2 is generated.

Example 31 Administration of Vaccine Compositions Using Dendritic Cells (DC)

Vaccines comprising peptide epitopes of the invention can be administered using APCs, or “professional” APCs such as DC. In this example, peptide-pulsed DC are administered to a patient to stimulate a CTL response in vivo. In this method, dendritic cells are isolated, expanded, and pulsed with a vaccine comprising peptide CTL and HTL epitopes of the invention. The dendritic cells are infused back into the patient to elicit CTL and HTL responses in vivo. The induced CTL and HTL then destroy or facilitate destruction, respectively, of the target cells that bear the proteins of the invention from which the epitopes in the vaccine are derived.

For example, a cocktail of epitope-comprising peptides is administered ex vivo to PBMC, or isolated DC therefrom. A pharmaceutical to facilitate harvesting of DC can be used, such as Progenipoietin™ (Monsanto, St. Louis, Mo.) or GM-CSF/IL-4. After pulsing the DC with peptides, and prior to reinfusion into patients, the DC are washed to remove unbound peptides.

As appreciated clinically, and readily determined by one of skill based on clinical outcomes, the number of DC reinfused into the patient can vary (see, e.g., Nature Med. 4:328, 1998; Nature Med. 2:52, 1996 and Prostate 32:272, 1997). Although 2-50×10⁶ DC per patient are typically administered, larger number of DC, such as 10⁷ or 10⁸ can also be provided. Such cell populations typically contain between 50-90% DC.

In some embodiments, peptide-loaded PBMC are injected into patients without purification of the DC. For example, PBMC generated after treatment with an agent such as Progenipoietin™ are injected into patients without purification of the DC. The total number of PBMC that are administered often ranges from 10⁸ to 10¹⁰. Generally, the cell doses injected into patients is based on the percentage of DC in the blood of each patient, as determined, for example, by immunofluorescence analysis with specific anti-DC antibodies. Thus, for example, if Progenipoietin™ mobilizes 2% DC in the peripheral blood of a given patient, and that patient is to receive 5×10⁶ DC, then the patient will be injected with a total of 2.5×10⁸ peptide-loaded PBMC. The percent DC mobilized by an agent such as Progenipoietin™ is typically estimated to be between 2-10%, but can vary as appreciated by one of skill in the art.

Ex Vivo Activation of CTL/HTL Responses

Alternatively, ex vivo CTL or HTL responses to protein antigens of the invention can be induced by incubating, in tissue culture, the patient's, or genetically compatible, CTL or HTL precursor cells together with a source of APC, such as DC, and immunogenic peptides. After an appropriate incubation time (typically about 7-28 days), in which the precursor cells are activated and expanded into effector cells, the cells are infused into the patient, where they will destroy (CTL) or facilitate destruction (HTL) of their specific target cells, i.e., tumor cells.

Example 32 An Alternative Method of Identifying Motif-Bearing Peptides

Another method of identifying and confirming motif-bearing peptides is to elute them from cells bearing defined MHC molecules. For example, EBV transformed B cell lines used for tissue typing have been extensively characterized to determine which HLA molecules they express. In certain cases these cells express only a single type of HLA molecule. These cells can be transfected with nucleic acids that express the antigens of interest, e.g. antigens of FIG. 2. Peptides produced by endogenous antigen processing of peptides produced as a result of transfection will then bind to HLA molecules within the cell and be transported and displayed on the cell's surface. Peptides are then eluted from the HLA molecules by exposure to mild acid conditions and their amino acid sequence determined, e.g., by mass spectral analysis (e.g., Kubo et al., J. Immunol. 152:3913, 1994). Because the majority of peptides that bind a particular HLA molecule are motif-bearing, this is an alternative modality for obtaining the motif-bearing peptides correlated with the particular HLA molecule expressed on the cell.

Alternatively, cell lines that do not express endogenous HLA molecules can be transfected with an expression construct encoding a single HLA allele. These cells can then be used as described, i.e., they can then be transfected with nucleic acids that encode proteins of the invention, to isolate peptides corresponding to proteins of FIG. 2 that have been presented on the cell surface. Peptides obtained from such an analysis will bear motif(s) that correspond to binding to the single HLA allele that is expressed in the cell.

As appreciated by one in the art, one can perform a similar analysis on a cell bearing more than one HLA allele and subsequently determine peptides specific for each HLA allele expressed. Moreover, one of skill would also recognize that means other than transfection, such as loading with a protein antigen, can be used to provide a source of antigen to the cell.

Example 33 Complementary Polynucleotides

Sequences complementary to FIG. 2 protein-encoding sequences, or any parts thereof, are used to detect, decrease, or inhibit expression of naturally occurring proteins of the invention. Although use of oligonucleotides comprising from about 15 to 30 base pairs is described, essentially the same procedure is used with smaller or with larger sequence fragments. Appropriate oligonucleotides are designed using, e.g., OLIGO 4.06 software (National Biosciences) and the coding sequences of proteins of the invention. To inhibit transcription, a complementary oligonucleotide is designed from the most unique 5′ sequence and used to prevent promoter binding to the coding sequence. To inhibit translation, a complementary oligonucleotide is designed to prevent ribosomal binding to a FIG. 2 protein-encoding transcript.

Example 34 Purification of Naturally-occurring or Recombinant FIG. 2 Proteins Using Specific Antibodies

Naturally occurring or recombinant FIG. 2 proteins are substantially purified by immunoaffinity chromatography using antibodies specific for a protein of the invention. An immunoaffinity column is constructed by covalently coupling, e.g., anti-protein of FIG. 2 antibodies to an activated chromatographic resin, such as CNBr-activated SEPHAROSE (Amersham Pharmacia Biotech). After the coupling, the resin is blocked and washed according to the manufacturer's instructions.

Media containing protein(s) of the invention are passed over the immunoaffinity column, and the column is washed under conditions that allow the preferential absorbance of proteins of the invention (e.g., high ionic strength buffers in the presence of detergent). The column is eluted under conditions that disrupt antibody/FIG. 2 protein binding (e.g., a buffer of pH 2 to pH 3, or a high concentration of a chaotrope, such as urea or thiocyanate ion), and GCR.P is collected.

Example 35 Identification of Molecules which Interact with Proteins of the Invention

FIG. 2 proteins, or biologically active fragments thereof, are labeled with 121 1 Bolton-Hunter reagent. (See, e.g., Bolton et al. (1973) Biochem. J. 133:529.) Candidate molecules previously arrayed in the wells of a multi-well plate are incubated with the labeled FIG. 2 proteins, washed, and any wells with labeled FIG. 2 protein complexes are assayed. Data obtained using different concentrations of FIG. 2 proteins are used to calculate values for the number, affinity, and association of FIG. 2 proteins with the candidate molecules.

Example 36 In Vivo Assay for Tumor Growth Promotion

The effect of a FIG. 2 protein on tumor cell growth is evaluated in vivo by gene overexpression in tumor-bearing mice. For example, SCID mice are injected subcutaneously on each flank with 1×10⁶ of either PC3, DU145 or 3T3 cells containing tkNeo empty vector or a nucleic acid sequence of the invention. At least two strategies can be used: (1) Constitutive expression under regulation of a promoter such as a constitutive promoter obtained from the genomes of viruses such as polyoma virus, fowlpox virus (UK 2,211,504 published 5 Jul. 1989), adenovirus (such as Adenovirus 2), bovine papilloma virus, avian sarcoma virus, cytomegalovirus, a retrovirus, hepatitis-B virus and Simian Virus 40 (SV40), or from heterologous mammalian promoters, e.g., the actin promoter or an immunoglobulin promoter, provided such promoters are compatible with the host cell systems, and (2) Regulated expression under control of an inducible vector system, such as ecdysone, tet, etc., provided such promoters are compatible with the host cell systems. Tumor volume is then monitored at the appearance of palpable tumors and followed over time to determine if the cells expressing a gene of the invention grow at a faster rate and whether tumors of a FIG. 2 protein-expressing cells demonstrate characteristics of altered aggressiveness (e.g. enhanced metastasis, vascularization, reduced responsiveness to chemotherapeutic drugs).

Additionally, mice can be implanted with 1×10⁵ of the same cells orthotopically to determine if a protein of the invention has an effect on local growth in the prostate or on the ability of the cells to metastasize, specifically to lungs, lymph nodes, and bone marrow.

The assay is also useful to determine the inhibitory effect of candidate therapeutic compositions, such as for example, FIG. 2 protein-related intrabodies, FIG. 2 gene-related antisense molecules and ribozymes.

Example 37 Tumors In Vivo, with Monoclonals Specific to a FIG. 2 Protein

The significant expression of a FIG. 2 proteins in cancer tissues of Table I and its restrictive expression in normal tissues, together with its expected cell surface expression, makes FIG. 2 proteins excellent targets for antibody therapy. Similarly, FIG. 2 proteins are a target for T cell-based immunotherapy. Thus, for FIG. 2 genes expressed, e.g., in prostate cancer, the therapeutic efficacy of anti-FIG. 2 protein mAbs in human prostate cancer xenograft mouse models is evaluated by using androgen-independent LAPC-4 and LAPC-9 xenografts (Craft, N., et al., Cancer Res, 1999. 59(19): p. 5030-6) and the androgen independent recombinant cell line PC3- of FIG. 2 (see, e.g., Kaighn, M. E., et al., Invest Urol, 1979. 17(1): p. 16-23); analogous models are used for other cancers.

Antibody efficacy on tumor growth and metastasis formation is studied, e.g., in a mouse orthotopic prostate cancer xenograft models and mouse kidney xenograft models. The antibodies can be unconjugated, as discussed in this Example, or can be conjugated to a therapeutic modality, as appreciated in the art. Anti-FIG. 2 protein mAbs inhibit formation of both the androgen-dependent LAPC-9 and androgen-independent PC3-FIG. 2 protein tumor xenografts. Anti-FIG. 2 protein mAbs also retard the growth of established orthotopic tumors and prolonged survival of tumor-bearing mice. These results indicate the utility of anti-FIG. 2 protein mAbs in the treatment of local and advanced stages of prostate cancer. (See, e.g., Saffran, D., et al., PNAS 10:1073-1078.)

Administration of the anti-FIG. 2 protein mAbs lead to retardation of established orthotopic tumor growth and inhibition of metastasis to distant sites, resulting in a significant prolongation in the survival of tumor-bearing mice. These studies indicate that proteins of the invention are attractive targets for immunotherapy and demonstrate the therapeutic potential of anti-FIG. 2 protein mAbs for the treatment of local and metastatic cancer. This example demonstrates that unconjugated FIG. 2 protein-related monoclonal antibodies are effective to inhibit the growth of human prostate tumor xenografts and human kidney xenografts grown in SCID mice; accordingly a combination of such efficacious monoclonal antibodies is also effective.

Tumor Inhibition Using Multiple Unconjugated mAbs

Materials and Methods

FIG. 2 Protein-related Monoclonal Antibodies:

Monoclonal antibodies are raised against proteins of the invention as described in Example 10. The antibodies are characterized by ELISA, Western blot, FACS, and immunoprecipitation for their capacity to bind to the respective protein of the invention. Epitope mapping data for, e.g., the anti-FIG. 2 protein mAbs, as determined by ELISA and Western analysis, indicate that the antibodies recognize epitopes on the respective FIG. 2 protein. Immunohistochemical analysis of prostate cancer tissues and cells with these antibodies is performed.

The monoclonal antibodies are purified from ascites or hybridoma tissue culture supernatants by Protein-G Sepharose chromatography, dialyzed against PBS, filter sterilized, and stored at −20° C. Protein determinations are performed by a Bradford assay (Bio-Rad, Hercules, Calif.). A therapeutic monoclonal antibody or a cocktail comprising a mixture of individual monoclonal antibodies is prepared and used for the treatment of mice receiving subcutaneous or orthotopic injections of LAPC-9 prostate tumor xenografts.

Cancer Xenografts and Cell Lines

The LAPC-9 xenograft, which expresses a wild-type androgen receptor and produces prostate-specific antigen (PSA), is passaged in 6- to 8-week-old male ICR-severe combined immunodeficient (SCID) mice (Taconic Farms) by s.c. trocar implant (Craft, N., et al., supra). The prostate carcinoma cell line PC3 (American Type Culture Collection) is maintained in RPMI supplemented with L-glutamine and 10% FBS.

Recombinant PC3 and 3T3-cell populations expressing a protein of the invention are generated by retroviral gene transfer as described in Hubert, R. S., et al., STEAP: a prostate-specific cell-surface antigen highly expressed in human prostate tumors. Proc Natl Acad Sci USA, 1999. 96(25): p. 14523-8. Anti-protein of the invention staining is detected by using an FITC-conjugated goat anti-mouse antibody (Southern Biotechnology Associates) followed by analysis on a Coulter Epics-XL flow cytometer.

Xenograft Mouse Models.

Subcutaneous (s.c.) tumors are generated by injection of 1×10⁶ LAPC-9, PC3, recombinant PC3-protein of the invention, 3T3 or recombinant 3T3-protein of the invention cells mixed at a 1:1 dilution with Matrigel (Collaborative Research) in the right flank of male SCID mice. To test antibody efficacy on tumor formation, i.p. antibody injections are started on the same day as tumor-cell injections. As a control, mice are injected with either purified mouse IgG (ICN) or PBS; or a purified monoclonal antibody that recognizes an irrelevant antigen not expressed in human cells. In preliminary studies, no difference is found between mouse IgG or PBS on tumor growth. Tumor sizes are determined by vernier caliper measurements, and the tumor volume is calculated as length×width×height. Mice with s.c. tumors greater than 1.5 cm in diameter are sacrificed. PSA levels are determined by using a PSA ELISA kit (Anogen, Mississauga, Ontario). Circulating levels of, e.g., anti-FIG. 2 protein mAbs are determined by a capture ELISA kit (Bethyl Laboratories, Montgomery, Tex.). (See, e.g., Saffran, D., et al., PNAS 10:1073-1078.)

Orthotopic injections are performed under anesthesia by using ketamine/xylazine. For prostate orthotopic studies, an incision is made through the abdominal muscles to expose the bladder and seminal vesicles, which then are delivered through the incision to expose the dorsal prostate. LAPC-9 or PC3 cells (5×10⁵) mixed with Matrigel are injected into each dorsal lobe in a 10-μl volume. To monitor tumor growth, mice are bled on a weekly basis for determination of PSA levels. The mice are segregated into groups for the appropriate treatments, with anti-protein of the invention or control mAbs being injected i.p.

Anti-FIG. 2 Protein mAbs Inhibit Growth of Respective FIG. 2 Protein-Expressing Xenograft-Cancer Tumors

The effect of anti-FIG. 2 protein mAbs on tumor formation is tested by using LAPC-9 and recombinant PC3-protein of the invention orthotopic models. As compared with the s.c. tumor model, the orthotopic model, which requires injection of tumor cells directly in the mouse prostate or kidney, respectively, results in a local tumor growth, development of metastasis in distal sites, deterioration of mouse health, and subsequent death (Saffran, D., et al., PNAS supra; Fu, X., et al., Int J Cancer, 1992. 52(6): p. 987-90; Kubota, T., J Cell Biochem, 1994. 56(1): p. 4-8). The features make the orthotopic model more representative of human disease progression and allowed us to follow the therapeutic effect of mAbs on clinically relevant end points.

Accordingly, tumor cells are injected into the mouse prostate or kidney, and 2 days later, the mice are segregated into two groups and treated with either: a) 200-500 μg, of anti-FIG. 2 protein Ab, or b) PBS three times per week for two to five weeks.

A major advantage of the orthotopic prostate-cancer model is the ability to study the development of metastases. Formation of metastasis in mice bearing established orthotopic tumors is studied by IHC analysis on lung sections using an antibody against a prostate-specific cell-surface protein STEAP expressed at high levels in LAPC-9 xenografts (Hubert, R. S., et al., Proc Natl Acad Sci USA, 1999. 96(25): p. 14523-8).

Mice bearing established orthotopic LAPC-9 or recombinant PC3-FIG. 2 protein tumors are administered 1000 μg injections of either anti-FIG. 2 protein mAbs or PBS over a 4-week period. Mice in both groups are allowed to establish a high tumor burden (PSA levels greater than 300 ng/ml for IAPC-9), to ensure a high frequency of metastasis formation in mouse lungs. Mice then are killed and their prostate and lungs are analyzed for the presence of tumor cells by IHC analysis.

These studies demonstrate a broad anti-tumor efficacy of anti-FIG. 2 protein antibodies on initiation and progression of prostate cancer in xenograft mouse models. Anti-FIG. 2 protein antibodies inhibit tumor formation of both androgen-dependent and androgen-independent tumors, retard the growth of already established tumors, and prolong the survival of treated mice. Moreover, anti-FIG. 2 protein mAbs demonstrate a dramatic inhibitory effect on the spread of local prostate tumor to distal sites, even in the presence of a large tumor burden. Thus, anti-FIG. 2 protein mAbs are efficacious on major clinically relevant end points (tumor growth), prolongation of survival, and health.

Example 38 Therapeutic and Diagnostic Use of Antibodies Specific to a Protein of FIG. 2

Anti-protein of FIG. 2 monoclonal antibodies are safely and effectively used for diagnostic, prophylactic, prognostic and/or therapeutic purposes in humans. Western blot and immunohistochemical analysis of cancer tissues and cancer xenografts with anti-protein of FIG. 2 mAb show strong extensive staining in carcinoma but significantly lower or undetectable levels in normal tissues. Detection of a protein of FIG. 2 in carcinoma and in metastatic disease demonstrates the usefulness of the mAb as a diagnostic and/or prognostic indicator. Anti-protein of FIG. 2 antibodies are therefore used in diagnostic applications such as immunohistochemistry of biopsy specimens to detect cancer from suspect patients.

As determined by flow cytometry, anti-protein of FIG. 2 mAbs specifically bind to carcinoma cells. Thus, anti-protein of FIG. 2 antibodies are used in diagnostic whole body imaging applications, such as radioimmunoscintigraphy and radioimmunotherapy, (see, e.g., Potamianos S., et. al. Anticancer Res 20(2A):925-948 (2000)) for the detection of localized and metastatic cancers that exhibit expression of a protein of FIG. 2. Shedding or release of an extracellular domain of a protein of FIG. 2 into the extracellular milieu, such as that seen for alkaline phosphodiesterase B10 (Meerson, N. R., Hepatology 27:563-568 (1998)), allows diagnostic detection of a protein of FIG. 2 by corresponding anti-protein of FIG. 2 antibodies in serum and/or urine samples from suspect patients.

Anti-protein of FIG. 2 antibodies that specifically bind protein of FIG. 2 are used in therapeutic applications for the treatment of cancers that express that protein of FIG. 2. Anti-protein of FIG. 2 antibodies are used as an unconjugated modality and as a conjugated form in which the antibodies are attached to one of various therapeutic or imaging modalities well known in the art, such as a prodrugs, enzymes or radioisotopes. In preclinical studies, unconjugated and conjugated anti-protein of FIG. 2 antibodies are tested for efficacy of tumor prevention and growth inhibition in the SCID mouse cancer xenograft models, e.g., kidney cancer models AGS-K3 and AGS-K6, (see, e.g., the Example entitled “Monoclonal Antibody-mediated Inhibition of Prostate Tumors In vivo”). Conjugated and unconjugated anti-protein of FIG. 2 antibodies are used as a therapeutic modality in human clinical trials either alone or in combination with other treatments as described in the following Examples.

Example 39 Human Clinical Trials for the Treatment and Diagnosis of Human Carcinomas Through Use of Human Antibodies Specific for a Protein of FIG. 2 In Vivo

Antibodies are used in accordance with the present invention which recognize an epitope of a FIG. 2 protein, and are used in the treatment of certain tumors such as those listed in Table I. Based upon a number of factors, including FIG. 2 protein expression levels, tumors such as those listed in Table I are presently preferred indications. In connection with each of these indications, three clinical approaches are successfully pursued.

-   -   I.) Adjunctive therapy: In adjunctive therapy, patients are         treated with antibodies of the invention, e.g., antibodies that         specifically bind a protein of the invention, in combination         with a chemotherapeutic or antineoplastic agent and/or radiation         therapy. Primary cancer targets, such as those listed in Table         I, are treated under standard protocols by the addition         anti-FIG. 2 protein antibodies to standard first and second line         therapy. Protocol designs address effectiveness as assessed by         reduction in tumor mass as well as the ability to reduce usual         doses of standard chemotherapy. These dosage reductions allow         additional and/or prolonged therapy by reducing dose-related         toxicity of the chemotherapeutic agent. Anti-FIG. 2 protein         antibodies are utilized in several adjunctive clinical trials in         combination with the chemotherapeutic or antineoplastic agents         adriamycin (advanced prostrate carcinoma), cisplatin (advanced         head and neck and lung carcinomas), taxol (breast cancer), and         doxorubicin (preclinical).     -   II.) Monotherapy: In connection with the use of the anti-FIG. 2         protein antibodies in monotherapy of tumors, the antibodies are         administered to patients without a chemotherapeutic or         antineoplastic agent. In one embodiment, monotherapy is         conducted clinically in end stage cancer patients with extensive         metastatic disease. Patients show some disease stabilization.         Trials demonstrate an effect in refractory patients with         cancerous tumors.     -   III.) Imaging Agent: Through binding a radionuclide (e.g.,         iodine or yttrium (I¹³¹, Y⁹⁰) to anti-FIG. 2 protein antibodies,         the radiolabeled antibodies are utilized as a diagnostic and/or         imaging agent. In such a role, the labeled antibodies localize         to both solid tumors, as well as, metastatic lesions of cells         expressing a protein of the invention. In connection with the         use of the anti-FIG. 2 protein antibodies as imaging agents, the         antibodies are used as an adjunct to surgical treatment of solid         tumors, as both a pre-surgical screen as well as a         post-operative follow-up to determine what tumor remains and/or         returns. In one embodiment, a (¹¹¹In)-FIG. 2 protein antibody is         used as an imaging agent in a Phase I human clinical trial in         patients having a carcinoma that expresses a protein of the         invention (by analogy see, e.g., Divgi et al. J. Natl. Cancer         Inst. 83:97-104 (1991)). Patients are followed with standard         anterior and posterior gamma camera. The results indicate that         primary lesions and metastatic lesions are identified Dose and         Route of Administration

As appreciated by those of ordinary skill in the art, dosing considerations can be determined through comparison with the analogous products that are in the clinic. Thus, anti-FIG. 2 protein antibodies can be administered with doses in the range of 5 to 400 mg/m², with the lower doses used, e.g., in connection with safety studies. The affinity of anti-FIG. 2 protein antibodies relative to the affinity of a known antibody for its target is one parameter used by those of skill in the art for determining analogous dose regimens. Further, anti-FIG. 2 protein antibodies that are fully human antibodies, as compared to the chimeric antibody, have slower clearance; accordingly, dosing in patients with such fully human anti-FIG. 2 protein antibodies can be lower, perhaps in the range of 50 to 300 mg/m², and still remain efficacious. Dosing in mg/m², as opposed to the conventional measurement of dose in mg/kg, is a measurement based on surface area and is a convenient dosing measurement that is designed to include patients of all sizes from infants to adults. Three distinct delivery approaches are useful for delivery of anti-FIG. 2 protein antibodies. Conventional intravenous delivery is one standard delivery technique for many tumors. However, in connection with tumors in the peritoneal cavity, such as tumors of the ovaries, biliary duct, other ducts, and the like, intraperitoneal administration may prove favorable for obtaining high dose of antibody at the tumor and to also minimize antibody clearance. In a similar manner, certain solid tumors possess vasculature that is appropriate for regional perfusion. Regional perfusion allows for a high dose of antibody at the site of a tumor and minimizes short term clearance of the antibody.

Clinical Development Plan (CDP)

Overview: The CDP follows and develops treatments of anti-FIG. 2 protein antibodies in connection with adjunctive therapy, monotherapy, and as an imaging agent. Trials initially demonstrate safety and thereafter confirm efficacy in repeat doses. Trials are open label comparing standard chemotherapy with standard therapy plus anti-FIG. 2 protein antibodies. As will be appreciated, one criteria that can be utilized in connection with enrollment of patients is FIG. 2 protein expression levels in their tumors as determined e.g. from biopsy specimens. As with any protein or antibody infusion-based therapeutic, safety concerns are related primarily to (i) cytokine release syndrome, i.e., hypotension, fever, shaking, chills; (ii) the development of an immunogenic response to the material (i.e., development of human antibodies by the patient to the antibody therapeutic, or HAHA response); and, (iii) toxicity to normal cells that express a protein of the invention. Standard tests and follow-ups are utilized to monitor each of these safety concerns. Anti-FIG. 2 protein antibodies are found to be safe upon human administration.

Example 40 Human Clinical Trial Adjunctive Therapy with Human Antibody (Specific to a Protein of FIG. 2) and Chemotherapeutic Agent

A phase I human clinical trial is initiated to assess the safety of six intravenous doses of a human anti-FIG. 2 protein antibody in connection with the treatment of a solid tumor, e.g., a cancer of a tissue listed in Table I. In the study, the safety of single doses of anti-FIG. 2 protein antibodies when utilized as an adjunctive therapy to an antineoplastic or chemotherapeutic agent, such as cisplatin, topotecan, doxorubicin, adriamycin, taxol, or the like, is assessed. The trial design includes delivery of six single doses of an anti-FIG. 2 protein antibody with dosage of antibody escalating from approximately about 25 mg/m² to about 275 mg/m² over the course of the treatment in accordance with the following schedule:

Day 0 Day 7 Day 14 Day 21 Day 28 Day 35 mAb Dose 25 mg/m² 75 mg/m² 125 mg/m² 175 mg/m² 225 mg/m² 275 mg/m² Chemotherapy + + + + + + (standard dose)

Patients are closely followed for one-week following each administration of antibody and chemotherapy. In particular, patients are assessed for the safety concerns mentioned above: (i) cytokine release syndrome, i.e., hypotension, fever, shaking, chills; (ii) the development of an immunogenic response to the material (i.e., development of human antibodies by the patient to the human antibody therapeutic, or HAHA response); and, (iii) toxicity to normal cells that express a protein of the invention. Standard tests and follow-up are utilized to monitor each of these safety concerns. Patients are also assessed for clinical outcome, and particularly reduction in tumor mass as evidenced by MRI or other imaging.

The anti-FIG. 2 protein antibodies are demonstrated to be safe and efficacious, Phase II trials confirm the efficacy and refine optimum dosing.

Example 41 Human Clinical Trial: Monotherapy with Human Antibody Specific to a Protein of FIG. 2

Anti-FIG. 2 protein antibodies are safe in connection with the above-discussed adjunctive trial, a Phase II human clinical trial confirms the efficacy and optimum dosing for monotherapy. Such trial is accomplished, and entails the same safety and outcome analyses, to the above-described adjunctive trial with the exception being that patients do not receive chemotherapy concurrently with the receipt of doses of anti-FIG. 2 protein antibodies.

Example 42 Human Clinical Trial: Diagnostic Imaging with Antibody Specific to a Protein of FIG. 2

Once again, as the adjunctive therapy discussed above is safe within the safety criteria discussed above, a human clinical trial is conducted concerning the use of anti-FIG. 2 protein antibodies as a diagnostic imaging agent. The protocol is designed in a substantially similar manner to those described in the art, such as in Divgi et al J. Natl. Cancer Inst. 83:97-104 (1991). The antibodies are found to be both safe and efficacious when used as a diagnostic modality.

Example 43 Effects on Tumor Growth and Promotion

The genes in FIG. 2 contribute to the growth of cancer cells. The role of these genes in tumor growth is investigated in a variety of primary and transfected cell lines including prostate, colon, bladder and kidney cell lines as well as NIH 3T3 cells engineered to stably express the gene of interest. Parental cells lacking the gene of interest and cells expressing that gene are evaluated for cell growth using a well-documented proliferation assay (Fraser S P, Grimes J A, Djamgoz M B. Prostate. 2000; 44:61, Johnson D E, Ochieng J, Evans S L. Anticancer Drugs. 1996, 7:288).

To determine the role of genes in FIG. 2 in the transformation process, the effect of individual genes in colony forming assays is investigated. Parental NIH3T3 cells lacking the gene of interest are compared to NHI-3T3 cells expressing that gene, using a soft agar assay under stringent and more permissive conditions (Song Z. et al. Cancer Res. 2000; 60:6730). It is found that genes set forth in FIG. 2 asversely affect transformation.

To determine the role of the genes of FIG. 2 in invasion and metastasis of cancer cells, a well-established assay is used, e.g., a Transwell Insert System assay (Becton Dickinson) (Cancer Res. 1999; 59:6010). Control cells, including prostate, colon, bladder and kidney cell lines lacking the gene of interest are compared to cells expressing that gene. Cells are loaded with the fluorescent dye, calcein, and plated in the top well of the Transwell insert coated with a basement membrane analog. Invasion is determined by fluorescence of cells in the lower chamber relative to the fluorescence of the entire cell population. It is found that genes set forth in FIG. 2 adversely invasion and/or metastasis.

The genes in FIG. 2 also play a role in cell cycle modulation and apoptosis. Parental cells and cells expressing the gene of interest are compared for differences in cell cycle regulation using a well-established BrdU assay (Abdel-Malek Z A. J Cell Physiol. 1988, 136:247). In short, cells are grown under both optimal (full serum) and limiting (low serum) conditions are labeled with BrdU and stained with anti-BrdU Ab and propidium iodide. Cells are analyzed for entry into the G1, S, and G2M phases of the cell cycle. Alternatively, the effect of stress on apoptosis is evaluated in control parental cells and cells expressing the gene of interest, including normal and tumor prostate, colon and lung cells. Engineered and parental cells are treated with various chemotherapeutic agents, such as etoposide, flutamide, etc, and protein synthesis inhibitors, such as cycloheximide. Cells are stained with annexin V-FITC and cell death is measured by FACS analysis. The modulation of cell death by genes of FIG. 2 play a critical role in regulating tumor progression and tumor load.

When a genes set for in FIG. 2, and/or its respective gene product, plays a role in cell growth, transformation, invasion or apoptosis, it is used as a target for diagnostic, prognostic, preventative and therapeutic purposes.

The present invention is not to be limited in scope by the embodiments disclosed herein, which are intended as single illustrations of individual aspects of the invention, and any that are functionally equivalent are within the scope of the invention. Various modifications to the models and methods of the invention, in addition to those described herein, will become apparent to those skilled in the art from the foregoing description and teachings, and are similarly intended to fall within the scope of the invention. Such modifications or other embodiments can be practiced without departing from the true scope and spirit of the invention.

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1. A method of inducing a mammalian immune response directed to a 74P3B3 protein having SEQ ID NO: 22, comprising: exposing cells of the immune system of a mammal to a protein consisting of SEQ ID NO: 22, whereby the mammalian immune response to the 74P3B3 protein is generated.
 2. The method of claim 1, wherein the protein comprises at least one B cell epitope.
 3. The method of claim 2, whereby the protein induces a B cell to generate antibodies that specifically bind to the protein.
 4. The method of claim 1, wherein the immune response comprises production of an antibody that binds specifically to the protein. 